Communication system

ABSTRACT

It is possible to efficiently transmit and receive signals containing uplink control information between a base station apparatus and a mobile station apparatus. 
     eREG is configured with a plurality of resources into which one DL PRB pair is divided, eCCE is configured with an aggregation of a plurality of eREGs, a second PDCCH is configured with an aggregation of one or more eCCEs, a PUCCH resource corresponds to each eCCE, a first reception processing unit receives information indicating a plurality of second PDCCH regions and information indicating a PUCCH resource in which association with eCCE of the second PDCCH region for each second PDCCH region is started, from the base station apparatus, and a first control unit configures a PUCCH resource, in which association with eCCE of the second PDCCH region is started, for each second PDCCH region, based on the received information.

TECHNICAL FIELD

The present invention relates to a communication system, a mobilestation apparatus, a base station apparatus, a communication method, andan integrated circuit, in which in a communication system configuredwith a plurality of mobile station apparatuses and a base stationapparatus, resources to be used in transmission and reception of uplinkcontrol information are efficiently controlled, the mobile stationapparatuses are capable of efficiently transmitting signals containingthe uplink control information to the base station apparatus, and thebase station apparatus is capable of efficiently receiving signalscontaining the uplink control information from the mobile stationapparatuses.

BACKGROUND ART

Evolution of a radio access scheme and a radio network of a cellularmobile communication (hereinafter, referred to as “Long Term Evolution(LTE (registered trademark))” or “Evolved Universal Terrestrial Radioaccess (EUTRA)”) has been standardized in a 3rd Generation PartnershipProject (3GPP (registered trademark)). In LTE, Orthogonal FrequencyDivision Multiplexing (OFDM) scheme, which is multicarrier transmission,is adopted as a communication scheme of wireless communication from abase station apparatus to a mobile station apparatus (referred to asdownlink (DL)). Further, in LTE, Single-Carrier Frequency DivisionMultiple Access (SC-FDMA) scheme, which is single carrier transmission,is adopted as a communication scheme of wireless communication from themobile station apparatus to the base station apparatus (referred to asuplink (UL)). In LTE, Discrete Fourier Transform-Spread OFDM (DFT-SpreadOFDM) scheme is adopted as the SC-FDMA scheme.

LTE is developed, and thus Long Term Evolution-Advanced (LTE-A) adoptinga new technology is specified. In LTE-A, at least the same channelstructure as that of LTE is supported. A channel means a medium to beused in transmission of signals. A channel to be used in a physicallayer is termed a physical channel, whereas a channel to be used in aMedium Access Control (MAC) layer is termed a logical channel. The typesof the physical channel includes a Physical Downlink Shared CHannel(PDSCH) to be used in transmission and reception of data and controlinformation of the downlink, a Physical Downlink Control CHannel (PDCCH)to be used in transmission and reception of control information of thedownlink, a Physical Uplink Shared CHannel (PUSCH) to be used intransmission and reception of data and control information of theuplink, a Physical Uplink Control CHannel (PUCCH) to be used intransmission and reception of control information of the uplink, aSynchronization CHannel (SCH) to be used for synchronizationestablishment of the downlink, a Physical Random Access CHannel (PRACH)to be used for synchronization establishment of the uplink, a PhysicalBroadcast CHannel (PBCH) to be used in transmission of systeminformation of the downlink, and the like. The mobile station apparatusor the base station apparatus maps and transmits signals which aregenerated from control information, data, and the like on each physicalchannel. Data which is transmitted on the physical downlink sharedchannel or the physical uplink shared channel is termed a transportblock.

Control information which is mapped on the physical uplink controlchannel is termed Uplink Control Information (UCI). The uplink controlinformation is control information (reception confirmationacknowledgement; ACK/NACK) indicating acknowledgement (ACK) or negativeacknowledgement (NACK) with respect to data mapped on the receivedphysical downlink shared channel, control information (SchedulingRequest: SR) indicating a request for allocation of an uplink resource,or control information (Channel Quality Indicator: CQI) indicatingreception quality (also referred to as channel quality) of the downlink.

<Cooperative Communication>

In order to reduce or suppress interference for the mobile stationapparatus in a cell edge region or to increase reception signal power,applying Cooperative Multipoint communication (CoMP communication) toLTE and LTE-A is being considered which performs communication betweenneighboring cells in cooperation with each other. In addition, forexample, the form in which the base station apparatus performscommunication by using a certain frequency band will be referred to as“a cell”. For example, as the CoMP communication, in a plurality ofcells, a different weighting signal process (pre-coding process) isapplied on a signal, a plurality of base station apparatuses cooperateto transmit the signal to the same mobile station apparatus (alsoreferred to as Joint Processing or Joint Transmission). This methodenables to improve a signal power-to-interference noise power ratio ofthe mobile station apparatus and improve the reception characteristicsof the mobile station apparatus. For example, as CoMP communication, amethod in which a plurality of cells cooperate to perform a schedulingfor the mobile station apparatus (Coordinated Scheduling: CS) is beingconsidered. This method enables to improve a signalpower-to-interference noise power ratio of the mobile station apparatus.For example, as the CoMP communication, a method in which a plurality ofcells cooperate to apply a beamforming on signals and transmit thesignals to the mobile station apparatus (Coordinated Beamforming: CB) isbeing considered. This method enables to improve a signalpower-to-interference noise power ratio of the mobile station apparatus.For example, as the CoMP communication, a method in which only one celltransmits signals by using a predetermined resource, other cells do nottransmit signals on a predetermined resource (Blanking and Muting) isbeing considered. This method enables to improve a signalpower-to-interference noise power ratio of the mobile station apparatus.

In addition, with respect to a plurality of cells to be used in thecooperative communication, different cells may be configured withdifferent base station apparatuses, different cells may be configuredwith different Remote Radio Heads (RRH) (more compact outdoor radio unitthan the base station apparatus, and also referred to as a Remote RadioUnit: RRU) which are managed by the same base station apparatus,different cells may be configured with a base station apparatus and RRHmanaged by the base station apparatus, or different cells may beconfigured with the base station apparatus and the RRH managed by a basestation apparatus different from the base station apparatus.

A base station apparatus having a wide coverage is generally referred toas a macro base station apparatus. A base station apparatus having anarrow coverage is generally referred to as a pico base stationapparatus or a femto base station apparatus. The RRH is consideredgenerally to operate in an area having a narrower coverage than that ofthe macro base station apparatus. The deployment of a communicationsystem configured with the macro base station apparatus and the RRH inwhich the coverage supported by the macro base station apparatusincludes all or a part of the coverage supported by the RRH is referredto as a heterogeneous network deployment. In a communication system ofsuch a heterogeneous network deployment, a method is considered in whichthe macro base station apparatus and the RRH cooperate to transmitsignals to the mobile station apparatus located within an overlappedcoverage. Here, the RRH is managed by the macro base station apparatusand transmission and reception thereof are controlled. In addition, themacro base station apparatus and the RRH are connected to each other bya wired line such as an optical fiber or a wireless line using a relaytechnology. In this manner, since the macro base station apparatus andthe RRH perform cooperative communication each using all or partiallythe same radio resource, it is possible to improve overall frequencyutilization efficiency (transmission capacity) within an area of acoverage which has built by the macro base station apparatus.

When a mobile station apparatus is located in the vicinity of the macrobase station apparatus or the RRH, the mobile station apparatus canperform single cell communication with the macro base station apparatusor the RRH. In other words, some mobile station apparatuses performcommunication with the macro base station apparatus or the RRH withoutusing the cooperative communication so as to transmit and receivesignals. For example, the macro base station apparatus receives anuplink signal from the mobile station apparatus located close to themacro station apparatus in distance. For example, the RRH receives anuplink signal from the mobile station apparatus located close to the RRHin distance. Further, when the mobile station apparatus is located inthe vicinity of the edge (cell edge) of a coverage built by the RRH,measures against the co-channel interference from the macro base stationapparatus is required. A method has been considered which reduces orsuppresses interference for the mobile station apparatus in the celledge region by using a CoMP scheme in which neighboring base stationscooperate with each other as a multi-cell communication (cooperativecommunication) between the macro base station apparatus and the RRH.

Further, it has been considered that the mobile station apparatusreceives signals transmitted from both the macro base station apparatusand the RRH by using cooperative communication in the downlink, andtransmits signals in a form suitable for either the macro base stationapparatus or the RRH in the uplink. For example, the mobile stationapparatus transmits uplink signals in transmission power that issuitable for the macro base station apparatus to receive the signals.For example, the mobile station apparatus transmits uplink signals intransmission power that is suitable for the RRH to receive the signals.This reduces unnecessary interference in the uplink, and improves thefrequency utilization efficiency.

It is necessary for the mobile station apparatus to obtain controlinformation indicating a modulation scheme, a coding rate, a spatialmultiplexing number, a transmission power adjustment value, allocationof resource, and the like which are used in data signals, with respectto a reception process of the data signals. With respect to LTE andLTE-A, it has been considered to introduce a new control channel(enhanced physical downlink control channel: ePDCCH) for transmittingcontrol information regarding the data signals (NPL 1). For example, ithas been considered to improve the capacities of all control channels.For example, it has been considered to support interference coordinationin a frequency domain for the enhanced physical downlink controlchannel. For example, it has been considered to support spatialmultiplexing for the enhanced physical downlink control channel. Forexample, it has been considered to support beamforming for the enhancedphysical downlink control channel. For example, it has been consideredto support diversity for the enhanced physical downlink control channel.For example, it has been considered to use the enhanced physicaldownlink control channel in a new type of carrier. For example, it hasbeen considered not to perform transmission of the reference signalwhich is common to all mobile station apparatuses within a cell, in thenew type of carrier. For example, it has been considered to furtherreduce the transmission frequency of the reference signal which iscommon to all mobile station apparatuses within the cell than theconventional transmission frequency, in the new type of carrier. Forexample, it has been considered to demodulate signals such as controlinformation by using a reference signal specific to the mobile stationapparatus, in the new type of carrier.

For example, as an application of beamforming, it has been considered toapply cooperative communication, and transmission through a plurality ofantennas to the enhanced physical downlink control channel Specifically,it has been considered that a plurality of base station apparatuses anda plurality of RRHs apply a pre-coding process on signals of theenhanced physical downlink control channel and apply the same pre-codingprocess on a reference signal (RS) for demodulating the signals of theenhanced physical downlink control channel Specifically, it has beenconsidered that a plurality of base station apparatuses and a pluralityof RRHs allocate the enhanced physical downlink control channel and RS,to which the same pre-coding process is applied, in a region ofresources in which the PDSCH is allocated, and transmit the enhancedphysical downlink control channel and RS. It has been considered that amobile station apparatus demodulates the signals of the enhancedphysical downlink control channel which is subjected to the samepre-coding process, by using the received RS which has been subjected tothe pre-coding process, so as to obtain control information. In thismethod, it is not necessary for the base station apparatus and themobile station apparatus to exchange information regarding thepre-coding process which is applied to the signal of the enhancedphysical downlink control channel.

For example, a method has been considered which configures signals ofthe enhanced physical downlink control channel by using resourcesseparated in the frequency domain so as to achieve an effect offrequency diversity, as the application of diversity. In contrast, amethod has been considered which configures signals of the enhancedphysical downlink control channel by using the resources which are notseparated in the frequency domain, when beamforming is applied to theenhanced physical downlink control channel.

A mapping method for resources configuring the enhanced physicaldownlink control channel has been considered. It has been considered tomake the unit of resources configuring one enhanced physical downlinkcontrol channel to be a set of physical resource block pairs of apredetermined number (NPL 2). For example, the set of a plurality ofphysical resource block pairs which is the unit of resources configuringone enhanced physical downlink control channel is referred to as anenhanced physical downlink control channel set (ePDCCH set). In NPL 2,it is considered to configure a plurality of enhanced physical downlinkcontrol channels which are configured with the physical resource blockpairs of a predetermined number, for the mobile station apparatus. Forexample, it is considered that in a plurality of mobile stationapparatuses for which a plurality of enhanced physical downlink controlchannel sets are configured, some enhanced physical downlink controlchannel sets are configured with a plurality of common physical resourceblock pairs and some different enhanced physical downlink controlchannel sets are configured with a plurality of different physicalresource block pairs. It is considered that the mobile station apparatusperforms a decoding process for detecting the enhanced physical downlinkcontrol channel, in each of the plurality of configured enhancedphysical downlink control channel sets.

Meanwhile, a method is considered which allocates resources of aphysical uplink control channel which are used in transmission andreception of ACK/NACK for the physical downlink shared channel to whichresources are allocated by downlink control information which istransmitted and received in an enhanced physical downlink controlchannel (NPL 3). A method is considered in which the resources of thephysical uplink control channel are implicitly determined based on alogical resource (enhanced Control Channel Element: eCCE) number that isused in the enhanced physical downlink control channel, without usingsignaling which explicitly indicates the resources of the physicaluplink control channel.

In NPL 3, with respect to resources of the physical uplink controlchannel which are used in transmission and reception of ACK/NACK for thephysical downlink shared channel to which resources are allocated bydownlink control information which is transmitted and received in theexisting physical downlink control channel, and with respect toresources of the physical uplink control channel which are used intransmission and reception of ACK/NACK for the physical downlink sharedchannel to which resources are allocated by downlink control informationwhich is transmitted and received in the enhanced physical downlinkcontrol channel, a method of allowing at least some resources to beshared is considered. In the existing physical downlink control channel,the method is considered in which the resources of the physical uplinkcontrol channel are implicitly determined based on the logical resource(Control Channel Element: CCE) number that is used in the physicaldownlink control channel, without using signaling which explicitlyindicates the resources of the physical uplink control channel, theresource of the physical uplink control channel in which the associationwith the control channel element is started, in other words, theresource of the physical uplink control channel in which the associationwith the control channel element of the minimum number is performed iscontrolled, and the mobile station apparatus is notified, in advance, ofinformation indicating the resource of the physical uplink controlchannel in which the association with the control channel element isstarted, from the base station apparatus. It is considered that in theenhanced physical downlink control channel, the resource of the physicaluplink control channel in which association with the enhanced controlchannel element of the enhanced physical downlink control channel isstarted is controlled independently of the resource of the physicaluplink control channel in which the association with the control channelelement of the existing physical downlink control channel is started,and the mobile station apparatus is notified, in advance, of informationindicating the resource of the physical uplink control channel in whichthe association with the enhanced control channel element is started,from the base station apparatus independently of the informationindicating the resource of the physical uplink control channel in whichthe association with the control channel element is started.

In the above method in which the resource of the physical uplink controlchannel is implicitly determined, the resources of a plurality ofphysical uplink control channels are reserved in advance for the uplink.Among a plurality of resources which are reserved, the resources whichare actually used in transmission and reception of uplink controlinformation for each subframe are dependent on the control channelelement of the physical downlink control channel which is used for eachsubframe and the enhanced control channel element of the enhancedphysical downlink control channel.

CITATION LIST Non-Patent Document

-   NPL 1: 3GPP TSG RAN WG1 #66bis, Zhuhai, China, 10-14, October, 2011,    R1-113589 “Way Forward on downlink control channel enhancements by    UE-specific RS”-   NPL 2: 3GPP TSG RAN WG1 #69, Prague, Czech Republic, 21-25, May,    2012, R1-121976 “Design Principle for E-PDCCH Multiplexing”-   NPL 3: 3GPP TSG RAN WG1 #69, Prague, Czech Republic, 21-25, May,    2012, R1-123013 “WF on PUCCH Format 1a/1b resource allocation for    ePDCCH based HARQ-ACKs”

DISCLOSURE OF THE INVENTION Problems to be Solved by the Invention

However, in the related studies, with respect to a method of allocatingresources of the physical uplink control channel which are used intransmission and reception of ACK/NACK for the physical downlink sharedchannel to which resources are allocated by downlink control informationwhich is transmitted and received in the enhanced physical downlinkcontrol channel, a case is not considered sufficiently in which aplurality of enhanced physical downlink control channel sets areconfigured in a plurality of mobile station apparatuses.

In the case where different mobile station apparatuses use the physicaluplink control channel which is configured with the same resources,signal collision occurs, the signals exert interference on each other,and the reception quality of the signal deteriorates. Meanwhile,preparing different resources in advance for respective mobile stationapparatuses, with respect to the resource of the physical uplink controlchannel which is reserved, in order to avoid collision of signals of theresource of the physical uplink control channel induces an increase inoverhead, and the capacity of a system deteriorates.

The present invention has been made in view of the above circumstances,an object is to provide a communication system, a mobile stationapparatus, a base station apparatus, a communication method, and anintegrated circuit, in which in a communication system configured with aplurality of mobile station apparatuses and a base station apparatus,resources to be used in transmission and reception of uplink controlinformation are efficiently controlled, the mobile station apparatus iscapable of efficiently transmitting signals containing uplink controlinformation to the base station apparatus, and the base stationapparatus is capable of efficiently receiving signals containing theuplink control information from the mobile station apparatus.

Means for Solving the Problems

(1) The present invention includes the following means in order toachieve the above objects. In other words, a communication system of thepresent invention is a communication system which is configured with aplurality of terminal apparatuses and a base station apparatus capableof communicating with the plurality of terminal apparatuses by usingEPDCCH and PUCCH, in which the base station apparatus includes a secondradio resource control unit configured to and/or programmed to configurea plurality of EPDCCH sets for each of the terminal apparatuses, and toconfigure a PUCCH resource, in which association with an ECCE index isstarted, for the configuration of each of the EPDCCH sets; and a secondtransmission processing unit configured to and/or programmed to transmitinformation indicating the configurations of the plurality of EPDCCHsets and a plurality of the PUCCH resources which are configured by thesecond radio resource control unit, to the terminal apparatuses, and theterminal apparatus includes a first reception processing unit configuredto and/or programmed to receive information indicating a plurality ofEPDCCH sets and information indicating a PUCCH resource offset for eachof the EPDCCH sets from the base station apparatus; a first radioresource control unit configured to and/or programmed to configure theplurality of EPDCCH sets, according to information received by the firstreception processing unit; and a first control unit configured to and/orprogrammed to configure a PUCCH resource, in which association with anECCE index is started, for each of the EPDCCH sets which are configuredby the first radio resource control unit, according to the informationreceived by the first reception processing unit.

(2) Further, a terminal apparatus of the present invention is a terminalapparatus which is capable of communicating with a base stationapparatus by using EPDCCH and PUCCH, and includes a first receptionprocessing unit configured to and/or programmed to receive informationindicating a plurality of EPDCCH sets and information indicating a PUCCHresource offset for each of the EPDCCH sets, from the base stationapparatus; a first radio resource control unit configured to and/orprogrammed to configure the plurality of EPDCCH sets, according to theinformation received by the first reception processing unit; and a firstcontrol unit configured to and/or programmed to configure a PUCCHresource, in which association with an ECCE index is started, for eachof the EPDCCH sets which are configured by the first radio resourcecontrol unit, according to the information received by the firstreception processing unit.

(3) Further, in the terminal apparatus of the present invention, thePUCCH is used in transmission and reception of ACK/NACK, and theACK/NACK corresponds to PDSCH data of which resource allocationinformation is represented by detected EPDCCH.

(4) Further, in the mobile station apparatus of the present invention, aPUCCH format 1a or a PUCCH format 1b is used for the PUCCH.

(5) Further, in the mobile station apparatus of the present invention,the first control unit is configured to and/or programmed to determinethe PUCCH resource that is used in transmission of the ACK/NACK, basedon at least an ECCE index of a minimum number among one or more ECCEsconfiguring the EPDCCH, which contains resource allocation informationof the PDSCH, and a PUCCH resource in which association with ECCE of anPDCCH set from which the EPDCCH is detected is started.

(6) Further, a base station apparatus of the present invention is a basestation apparatus capable of communicating with a plurality of terminalapparatuses by using EPDCCH and PUCCH, and includes a second radioresource control unit configured to and/or programmed to configure aplurality of EPDCCH sets and configures a PUCCH resource in which theassociation with an ECCE index is started, for the configuration of eachof the EPDCCH sets; and a second transmission processing unit configuredto and/or programmed to transmit information indicating theconfigurations of the plurality of EPDCCH sets and a plurality of thePUCCH resources which are configured by the second radio resourcecontrol unit, to the terminal apparatuses.

(7) Further, in the base station apparatus of the present invention, thePUCCH is used in transmission and reception of ACK/NACK, and theACK/NACK corresponds to PDSCH data of which resource allocationinformation is represented by transmitted EPDCCH.

(8) Further, in the base station apparatus of the present invention, aPUCCH format 1a or a PUCCH format 1b is used for the PUCCH.

(9) Further, a communication method of the present invention is acommunication method which is used in a terminal apparatus capable ofcommunicating with a base station apparatus by using EPDCCH and PUCCH,and includes at least a step of receiving information indicating aplurality of EPDCCH sets and information indicating a PUCCH resourceoffset for each of the EPDCCH sets, from the base station apparatus; astep of configuring a plurality of EPDCCH sets, according to informationreceived by the first reception processing unit; and a step ofconfiguring a PUCCH resource, in which association with an ECCE index isstarted, for each of the EPDCCH sets which are configured by the firstradio resource control unit, according to the received information.

(10) Further, a communication method of the present invention is acommunication method which is used in a base station apparatus capableof communicating with a plurality of terminal apparatuses by usingEPDCCH and PUCCH, and includes at least a step of configuring aplurality of EPDCCH sets and configuring a PUCCH resource, in which theassociation with an ECCE index is started, for the configuration of eachof the EPDCCH sets; and a step of transmitting information indicatingthe configurations of the plurality of EPDCCH sets which are configuredand the plurality of PUCCH resources, to the terminal apparatuses.

(11) Further, an integrated circuit of the present invention is anintegrated circuit which is implemented in a terminal apparatus capableof communicating with a base station apparatus by using EPDCCH andPUCCH, and causes the terminal apparatus to exert a series of functionsincluding a function of receiving information indicating a plurality ofEPDCCH sets and information indicating a PUCCH resource offset for eachof the EPDCCH sets, from the base station apparatus; and a function ofconfiguring a plurality of EPDCCH sets, according to informationreceived by the first reception processing unit; and a function ofconfiguring a PUCCH resource, in which association with an ECCE index isstarted, for each of the EPDCCH sets which are configured by the firstradio resource control unit, according to the received information.

(12) Further, an integrated circuit of the present invention is anintegrated circuit which is implemented in a base station apparatuscapable of communicating with a plurality of terminal apparatuses byusing EPDCCH and PUCCH, and causes the base station apparatus to exert aseries of functions including a function of configuring a plurality ofEPDCCH sets and configuring a PUCCH resource, in which association withan ECCE index is started, for the configuration of each of the EPDCCHsets; and a function of transmitting information indicating theconfigurations of the plurality of EPDCCH sets which are configured andthe plurality of PUCCH resources, to the terminal apparatuses.

Although the present invention is disclosed herein as improvements of acommunication system, a mobile station apparatus, a base stationapparatus, a communication method, and an integrated circuit in which aregion having a possibility of the control channel being allocatedtherein for the mobile station apparatus is configured by a base stationapparatus, a communication scheme to which the present invention isapplicable is not limited to communication schemes such as LTE or LTE-Ahaving upward compatibility with LTE. For example, the present inventioncan be applied to a Universal Mobile Telecommunications System (UMTS).

Effects of the Invention

According to the present invention, a mobile station apparatus iscapable of efficiently transmitting a signal containing uplink controlinformation to a base station apparatus, the base station apparatus iscapable of efficiently receiving the signal containing the uplinkcontrol information from the mobile station apparatus, and thus it ispossible to realize more efficient communication system.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic block diagram showing a configuration of a basestation apparatus 3 according to an embodiment of the present invention.

FIG. 2 is a schematic block diagram showing a configuration of atransmission processing unit 107 of the base station apparatus 3according to the embodiment of the present invention.

FIG. 3 is a schematic block diagram showing a configuration of areception processing unit 101 of the base station apparatus 3 accordingto the embodiment of the present invention.

FIG. 4 is a schematic block diagram showing a configuration of a mobilestation apparatus 5 according to the embodiment of the presentinvention.

FIG. 5 is a schematic block diagram showing a configuration of areception processing unit 401 of the mobile station apparatus 5according to the embodiment of the present invention.

FIG. 6 is a schematic block diagram showing a configuration of atransmission processing unit 407 of the mobile station apparatus 5according to the embodiment of the present invention.

FIG. 7 is a flowchart showing an example of a process regarding aconfiguration of a PUCCH resource offset for each second PDCCH region ofthe mobile station apparatus 5 according to the embodiment of thepresent invention.

FIG. 8 is a flowchart showing an example of a process regarding aconfiguration of a PUCCH resource offset for each second PDCCH region ofthe base station apparatus 3 according to the embodiment of the presentinvention.

FIG. 9 is a diagram schematically describing an overall appearance of acommunication system according to an embodiment of the presentinvention.

FIG. 10 is a diagram showing a schematic configuration of a time frameof a downlink from the base station apparatus 3 or the RRH 4 to themobile station apparatus 5, according to the embodiment of the presentinvention.

FIG. 11 is a diagram showing an example of mapping of the downlinkreference signals within a downlink subframe of a communication system 1according to an embodiment of the present invention.

FIG. 12 is a diagram showing an example of mapping of the downlinkreference signals within a downlink subframe of the communication system1 according to the embodiment of the present invention.

FIG. 13 is a diagram showing a DL PRB pair to which a Channel StateInformation-Reference Signals (CSI-RS) for eight antenna ports aremapped.

FIG. 14 is a diagram showing a schematic configuration of a time frameof an uplink from the mobile station apparatus 5 to the base stationapparatus 3 and the RRH 4, according to the embodiment of the presentinvention.

FIG. 15 is a diagram illustrating the configuration and the number ofACK/NACK PUCCH resource in the communication system according to theembodiment of the present invention.

FIG. 16 is a diagram illustrating a logical relationship between a firstPDCCH and a CCE of the communication system 1 according to theembodiment of the present invention.

FIG. 17 is a diagram showing an example of mapping of a resource elementgroup in a downlink subframe of the communication system 1 according tothe embodiment of the present invention.

FIG. 18 is a diagram showing an example of a schematic configuration ofthe second PDCCH in the communication system 1 according to theembodiment of the present invention.

FIG. 19 is a diagram illustrating a logical relationship between thesecond PDCCH and an E-CCE of the communication system 1 according to theembodiment of the present invention.

FIG. 20 is a diagram illustrating an example of Localized mapping of theembodiment of the present invention.

FIG. 21 is a diagram illustrating an example of Distributed mapping ofthe embodiment of the present invention.

FIG. 22 is a diagram illustrating an example of a configuration of eREGof the embodiment of the present invention.

FIG. 23 is a diagram illustrating an example of a configuration of eREGof the embodiment of the present invention.

FIG. 24 is a diagram illustrating an example of monitoring of a secondPDCCH of the mobile station apparatus 5 according to the embodiment ofthe present invention.

FIG. 25 is a diagram conceptually describing association betweenACK/NACK PUCCH resource and eCCE of the second PDCCH region of theembodiment of the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION

The technology described herein may be used in various wirelesscommunication systems such as a Code Division Multiple Access (CDMA)system, a Time Division Multiple Access (TDMA) System, a FrequencyDivision Multiple Access (FDMA) system, an Orthogonal FDMA (OFDMA)system, a Single Carrier FDMA (SC-FDMA) system, and other systems. Theterms “system” and “network” may be often used synonymously. The CDMAsystem can implement wireless technologies (standards) such as UniversalTerrestrial Radio Access (UTRA) or cdma2000 (registered trademark). TheUTRA includes Wideband CDMA (WCDMA (registered trademark)) and otherimproved types of CDMA. The cdma2000 includes IS-2000, IS-95, and IS-856standards. The TDMA system can implement a wireless technology such as aGlobal System for Mobile Communications (GSM (registered trademark)).The OFDMA system can implement wireless technologies such as EvolvedUTRA (E-UTRA), Ultra Mobile Broadband (UMB), IEEE802.11 (Wi-Fi),IEEE802.16 (WiMAX), IEEE802.20, and Flash-OFDM (registered trademark).3GPP Long Term Evolution (LTE) is an E-UTRA employing the OFDMA on adownlink and SC-FDMA on an uplink. LTE-A is an improved LTE system,wireless technology, and standard. UTRA, E-UTRA, LTE, LTE-A and GSM aredescribed in documents issued from organizations named the 3rdGeneration Partnership Project (3GPP). The cdma2000 and the UMB aredescribed in documents issued from organizations named the 3rdGeneration Partnership Project 2 (3GPP2). For clarity, as some aspectsof the present technology, data communication in LTE and LTE-A will bedescribed below, and the terms used in LTE and LTE-A are used in thedescription below.

Hereinafter, embodiments of the present invention will be described indetail with reference to drawings. An overview of a communication systemaccording to the present embodiment and a configuration of a radio framewill be described using FIGS. 9 to 25. A configuration of thecommunication system according to the present embodiment will bedescribed using FIGS. 1 to 6. An operation process of the communicationsystem according to the present embodiment will be described using FIGS.7 and 8.

FIG. 9 is a diagram schematically describing an overall appearance of acommunication system according to an embodiment of the presentinvention. In the communication system 1 illustrated in FIG. 9, a basestation apparatus (also referred to as an eNodeB, a NodeB, a BaseStation (BS), an Access Point (AP), and a macro base station) 3, aplurality of RRHs (also referred to as a Remote Radio Head, an apparatushaving an outdoor wireless unit smaller than the base station apparatus,and a Remote Radio Unit (RRU)) 4A, 4B, and 4C, a plurality of mobilestation apparatuses (also referred to as User Equipment (UE), a MobileStation (MS), a Mobile Terminal (MT), a terminal, a terminal apparatus,and a mobile terminal) 5A, 5B, and 5C perform communication with eachother. Hereinafter, in the present embodiment, a description will bemade appropriately while the RRHs 4A, 4B, and 4C are referred to as aRRH 4 and the mobile station apparatuses 5A, 5B, and 5C are referred toas a mobile station apparatus 5. In the communication system 1, the basestation apparatus 3 and the RRH 4 cooperate to perform communicationwith the mobile station apparatus 5. In FIG. 9, the base stationapparatus 3 and the RRH 4A perform cooperative communication with themobile station apparatus 5A, the base station apparatus 3 and the RRH 4Bperform cooperative communication with the mobile station apparatus 5B,and the base station apparatus 3 and the RRH 4C perform cooperativecommunication with the mobile station apparatus 5C.

In addition, the RRH may be referred to as a special form of the basestation apparatus. For example, it may be said that the RRH is a basestation apparatus which has only a signal processing unit and for whichconfiguration of parameters used in the RRH, a scheduling determinationand the like are performed by another base station apparatus.Accordingly, it should be noted that the expression of the base stationapparatus 3 appropriately includes the RRH 4 in the followingdescription.

<Cooperative Communication>

The communication system 1 according to the embodiment of the presentinvention uses cooperative communication (Cooperative Multipoint (CoMP)communication) in which a plurality of cells cooperate to performtransmission and reception of signals. In addition, for example, a formin which the base station apparatus performs communication using onefrequency band will be referred to as “a cell”. For example, as thecooperative communication, different weighting signal processes(pre-coding process) are applied to signals in a plurality of cells (thebase station apparatus 3 and the RRH 4), and the base station apparatus3 and the RRH 4 cooperate to transmit the signals to the same mobilestation apparatus 5 (Joint Processing, Joint Transmission). For example,as the cooperative communication, a plurality of cells (base stationapparatus 3 and the RRH 4) cooperate to perform a scheduling for themobile station apparatus 5 (Coordinated Scheduling: CS). For example, asthe cooperative communication, a plurality of cells (base stationapparatus 3 and the RRH 4) cooperate to apply a beamforming on signalsand transmit the signals to the mobile station apparatus 5 (CoordinatedBeamforming: CB). For example, as the cooperative communication, onlyone cell (the base station apparatus 3 or the RRH 4) transmits a signalby using a predetermined resource and the other cell (the base stationapparatus 3 or the RRH 4) does not transmit a signal by using thepredetermined resource (Blanking and Muting). For example, ascooperative communication, a cell to be used in transmission is selectedamong a plurality of cells (the base station apparatus 3 and the RRH 4)for each subframe and a signal is transmitted to the mobile stationapparatus 5 (Dynamic Point Switching: DPS).

In addition, although a description is omitted in the embodiments of thepresent invention, with respect to a plurality of cells used in thecooperative communication, different cells may be configured withdifferent base station apparatuses 3, may be configured with differentRRHs 4 managed by the same base station apparatus 3, or may beconfigured with a RRH 4 managed by the base station apparatus 3 and abase station apparatus 3 which is different from the base stationapparatus 3.

In addition, although a plurality of cells are used as physicallydifferent cells, they may be used as logically the same cells.Specifically, it may be configured that a common cell identifier(Physical cell ID) is used in each cell. For example, although commonphysical cell ID is used in physically different cells, other differentvirtual cell IDs are used in respective cells. For example, such a cellis referred to as a Virtual Cell. A configuration in which a pluralityof transmission apparatuses (the base station apparatus 3 and the RRH 4)transmit common signals to the same reception apparatus by using thesame frequency band is also referred to as a Single Frequency Network(SFN).

The deployment of the communication system 1 of the embodiment of thepresent invention is assumed as the deployment of a heterogeneousnetwork. The communication system 1 is configured with the base stationapparatus 3 and the RRH 4, and is configured such that the coveragesupported by the base station apparatus 3 includes all or a part of thecoverage supported by the RRH 4. Here, the coverage means an area forrealizing communication while satisfying a request. In the communicationsystem 1, the base station apparatus 3 and the RRH 4 cooperate totransmit signals to the mobile station apparatus 5 located within anoverlapped coverage. Here, the RRH 4 is managed by the base stationapparatus 3, and transmission and reception thereof is controlled. Inaddition, the base station apparatus 3 and the RRH 4 are connected by awired line such as an optical fiber or a wireless line using a relaytechnology.

When the mobile station apparatus 5 is located in the vicinity of thebase station apparatus 3 or the RRH 4, the mobile station apparatus 5may use single cell communication with the base station apparatus 3 orthe RRH 4. In other words, some mobile station apparatuses 5 may performcommunication with the base station apparatus 3 or the RRH 4 and performtransmission and reception of signals, while not using the cooperativecommunication. For example, the base station apparatus 3 may receiveuplink signals from the mobile station apparatus 5 close to the basestation apparatus in distance. For example, the RRH 4 may receive uplinksignals from the mobile station apparatus 5 close to the RRH indistance. Further, for example, both the base station apparatus 3 andthe RRH 4 may receive uplink signals from the mobile station apparatus 5located in the vicinity of an edge (cell edge) of a coverage built bythe RRH 4.

Further, the mobile station apparatus 5 may receive signals transmittedfrom both the base station apparatus 3 and the RRH 4 by using thecooperative communication in the downlink, and may transmit signals in aform suitable for any of the base station apparatus 3 or the RRH 4 inthe uplink. For example, the mobile station apparatus 5 transmits uplinksignals in transmission power suitable for the base station apparatus 3to receive signals. For example, the mobile station apparatus 5transmits uplink signals in transmission power suitable for the RRH 4 toreceive signals.

A plurality of RRHs 4 may simultaneously transmit different signals byusing the same physical resource, in the downlink. For example, an RRH4A, an RRH 4B, and an RRH 4C transmit reference signals usingrespectively different scrambling sequences in the downlink. In thismanner, an aspect of performing communication with a plurality of mobilestation apparatuses which are spatially separated, by using the samephysical resource is referred to as Cell-splitting. A plurality of RRHs4 form communication areas in a coverage area of one base stationapparatus 3, and virtual cells are configured by respective RRHs 4. Insuch a cell deployment, the mobile station apparatus 5 does notrecognize the existence of a virtual cell, therefore, even when themobile station apparatus 5 moves to the different virtual cell, ahandover procedure is not executed.

The base station apparatus 3 and the RRH 4 may simultaneously transmitdifferent signals by using the same physical resource in the downlink.For example, the base station apparatus 3 and the RRH 4 transmitreference signals using respectively different scrambling sequences inthe downlink. The base station apparatus 3 and the RRH 4 respectivelyperform different pre-coding processes on the signals to be transmittedand control beams of signals for the mobile station apparatuses 5 ineach area, such that even when the same resource is used in thefrequency domain and the time domain, the base station apparatus 3 andthe RRH 4 realize relatively high orthogonality for the signals amongmobile station apparatuses 5 and reduce co-channel interference. Such atechnology is referred to as Multi-User (MU)-MIMO. Since signals amongthe mobile station apparatuses 5 are spatially demultiplexed, such atechnology is also referred to as Space Division Multiple Access (SDMA).The MU-MIMO using reference signals using different scrambling sequencesis referred to as MU-MIMO with quasi-orthogonal RS.

In FIG. 9, it is assumed that an area near to the RRH 4A is an area A,an area near to the RRH 4B is an area B, and an area near to the RRH 4Cis an area C. In the area of the base station apparatus 3, differentpre-coding processes are executed on a second PDCCH and a UE-specificRS, described later, which are respectively used in the mobile stationapparatus 5 located in the area A, the mobile station apparatus 5located in the area B, and the mobile station apparatus 5 located in thearea C. The regions in which the second PDCCH may be allocated areseparately configured and the pre-coding process may be separatelyapplied, with respect to the mobile station apparatus 5 located in thearea A, the mobile station apparatus 5 located in the area B, and themobile station apparatus 5 located in the area C.

In the communication system 1, the DownLink (DL) which is acommunication direction from the base station apparatus 3 or the RRH 4to the mobile station apparatus 5 is configured to include a downlinkpilot channel, a Physical Downlink Control CHannel (PDCCH), and aPhysical Downlink Shared CHannel (PDSCH). The cooperative communicationis applied to or is not applied to the PDSCH. The PDCCH is configuredwith a first PDCCH and a second PDCCH (enhanced physical downlinkcontrol channel (enhanced PDCCH: e-PDCCH)). The downlink pilot channelis configured with a first type of reference signal (CRS describedlater) used in demodulating the PDSCH, the first PDCCH and a second typeof reference signal (UE-specific RS described later) used indemodulating the PDSCH and the second PDCCH, and a third type ofreference signal (CSI-RS described later).

In addition, from one viewpoint, the first PDCCH is a physical channelin which the same transmission ports (an antenna port and a transmitantenna) as the first type of reference signal is used. Further, thesecond PDCCH is a physical channel in which the same transmission portas the second type of reference signal is used. The mobile stationapparatus 5 demodulates the signals mapped to the first PDCCH by usingthe first type of reference signal, and demodulates the signals mappedto the second PDCCH by using the second type of reference signal. Thefirst type of reference signal is a reference signal which is common toall mobile station apparatuses 5 within a cell, inserted into almost allresource blocks and available also in any mobile station apparatus 5.Therefore, any mobile station apparatus 5 can demodulate the firstPDCCH. In contrast, the second type of reference signal is a referencesignal which is inserted into only an allocated resource block. Thesecond type of reference signal can be subjected to a pre-coding processadaptively in the same way as data.

In addition, from one viewpoint, the first PDCCH is a control channelallocated in OFDM symbols in which the PDSCH is not allocated. Further,the second PDCCH is a control channel allocated in the OFDM symbols inwhich the PDSCH is allocated. In addition, from one viewpoint, the firstPDCCH is a control channel in which signals are basically allocated overall PRBs (PRB of a first slot) of the downlink system band, and thesecond PDCCH is a control channel in which signals are allocated overPRB pairs (PRB) configured by the base station apparatus 3 within thedownlink system band. In addition, although a detailed description willbe made later, from one viewpoint, different signal configurations areused in the first PDCCH and the second PDCCH. A CCE structure describedlater is used in the signal configuration in the first PDCCH, and anenhanced CCE (eCCE) (second element) structure described later is usedin the signal configuration in the second PDCCH. In other words, thefirst PDCCH and the second PDCCH are different in a minimum unit(element) of resources used in the configuration of one control channel,and respective control channels are configured to include one or morerespective minimum units.

Further, in the communication system 1, the UpLink (UL) which is acommunication direction from the mobile station apparatus 5 to the basestation apparatus 3 or the RRH 4 is configured to include a PhysicalUplink Shared CHannel (PUSCH), an uplink pilot channel (Uplink ReferenceSignal (UL RS), Sounding Reference Signal (SRS), and DemodulationReference Signal (DM RS)), and a Physical Uplink Control CHannel(PUCCH). The channel means a medium used in transmission of signals. Achannel used in a physical layer is termed a physical channel, whereas achannel used in a Medium Access Control (MAC) layer is termed a logicalchannel.

Further, the present invention may be applied to a communication systemof a case, for example, where the cooperative communication is appliedto the downlink, and of a case, for example, where transmission througha plurality of antennas is applied to the downlink, and for simplicityof explanation, although a case where the cooperative communication isnot applied to the uplink and a case where transmission through aplurality of antennas are not applied to the uplink have been described,the present invention is not limited to such cases.

The PDSCH is a physical channel used in transmission and reception ofdata and control information of the downlink (different from the controlinformation transmitted on the PDCCH). The PUSCH is a physical channelused in transmission and reception of data and control information ofthe uplink (different from the control information transmitted in thedownlink). The PUCCH is a physical channel used in transmission andreception of control information of the uplink (Uplink ControlInformation (UCI)). As the types of the UCI, a reception confirmationacknowledgement (ACK/NACK) indicating a positive ACKnowledgement (ACK)or a Negative ACKnowledgement (NACK) for the data of the downlink ofPDSCH, a Scheduling request (SR) indicating whether the allocation of aresource is requested or not, and the like are used. As the types ofother physical channels, a Synchronization CHannel (SCH) used forsynchronization establishment of the downlink, a Physical Random AccessCHannel (PRACH) used for synchronization establishment of the uplink, aPhysical Broadcast CHannel (PBCH) used in transmission of systeminformation (also referred to as a System Information Block (SIB)) ofthe downlink, and the like are used. Further, the PDSCH is used intransmission of system information of the downlink.

The mobile station apparatus 5, the base station apparatus 3, or the RRH4 allocate signals which are generated from control information, data,and the like in each physical channel, and transmit the signals. Themobile station apparatus 5, the base station apparatus 3, or the RRH 4receives each physical channel in which signals generated from controlinformation, data, and the like are mapped and transmitted. The datatransmitted in the PDSCH or the PUSCH is referred to as a transportblock. Further, an area which is managed by the base station apparatus 3or the RRH 4 is referred to as a cell.

<Configuration of Downlink Time Frame>

FIG. 10 is a diagram showing a schematic configuration of a time frameof a downlink from the base station apparatus 3 or the RRH 4 to themobile station apparatus 5, according to the embodiment of the presentinvention. In FIG. 10, the horizontal axis represents a time domain andthe vertical axis represents a frequency domain. The downlink time frameis a unit of allocation of resources and the like, and is configuredwith a pair (also referred to as Physical Resource Block pair (PRBpair)) of Resource Blocks (RB) (also referred to as a Physical ResourceBlock (PRB)) configured with a frequency band and a time band having apredetermined width in the downlink. One downlink PRB pair (alsoreferred to as a downlink Physical Resource Block pair (DL PRB pair)) isconfigured with two consecutive PRBs in the time domain in the downlink(also referred to as a DownLink Physical Resource Block (DL PRB)).

Further, in FIG. 10, one DL PRB is configured with 12 subcarriers in thefrequency domain in the downlink (also referred to as a downlinksubcarrier), and seven Orthogonal Frequency Division Multiplexing (OFDM)symbols in the time domain. The downlink system band (referred to as adownlink system band) is a downlink communication band of the basestation apparatus 3 or the RRH 4. For example, the downlink systembandwidth (referred to as a downlink system bandwidth) is configuredwith a frequency bandwidth of 20 MHz.

In addition, a plurality of DL PRBs (DP PRB pairs) are allocatedaccording to the downlink system bandwidth in the downlink system band.For example, the downlink system band of the frequency bandwidth of 20MHz is configured with 110 DL PRBs (DP PRB pairs).

Further, in the time domain illustrated in FIG. 10, there are a slotconfigured with 7 OFDM symbols (also referred to as a downlink slot),and a subframe configured with 2 downlink slots (also referred to as adownlink subframe). In addition, a unit configured with one downlinksubcarrier and one OFDM symbol is referred to as a Resource Element (RE)(downlink resource element). At least the PDSCH used in transmission ofinformation data (referred to as a Transport Block) and the first PDCCHand the second PDCCH which are used in transmission of controlinformation for the PDSCH are allocated in respective downlinksubframes. In FIG. 10, the first PDCCH is configured with the first tothird OFDM symbols in the downlink subframe, and the PDSCH and thesecond PDCCH are configured with the fourth to 14th OFDM symbols in thedownlink subframe. In addition, the PDSCH and the second PDCCH areallocated in different DL PRB pairs. In addition, the number of OFDMsymbols configuring the first PDCCH and the number of OFDM symbolsconfiguring the PDSCH and the second PDCCH may vary depending onrespective downlink subframes. In addition, the number of OFDM symbolsconfiguring the second PDCCH may be fixed. For example, irrespective ofthe number of OFDM symbols configuring the first PDCCH, and the numberof OFDM symbols configuring the PDSCH, the second PDCCH may beconfigured with the fourth to 14th OFDM symbols in the downlinksubframe.

Further, in FIG. 10, one or more first PDCCHs are allocated in theresources that are indicated as the first PDCCH. Further, in FIG. 10,one or more second PDCCHs are allocated in the resources that areindicated as the second PDCCH. Further, in FIG. 10, one or more PDSCHsare allocated in the resources that are indicated as the PDSCH.

Although it is not illustrated in FIG. 10, the downlink pilot channelsused in transmission of the Reference signal (RS) of the downlink (alsoreferred to as a downlink reference signal) are Distributed andallocated in a plurality of the downlink resource elements. Here, thedownlink reference signal is configured with the first type of referencesignal, the second type of reference signal, and the third type ofreference signal which are of at least different types. For example, thedownlink reference signal is used in estimation of the channel change ofthe PDSCH and the PDCCH (first PDCCH and second PDCCH). The first typeof reference signal is used in demodulation of the PDSCH and the firstPDCCH and is referred to as a Cell specific RS (CRS). The second type ofreference signal is used in demodulation of the PDSCH and the secondPDCCH and is also referred to as a UE-specific RS. For example, thethird type of reference signal is used only in estimation of the channelchange, and is also referred to as a Channel State Information RS(CSI-RS). The downlink reference signal is a known signal in thecommunication system 1. In addition, the number of the downlink resourceelements configuring the downlink reference signal may depend on thenumber of transmit antennas (antenna ports) in used in communicationfrom the base station apparatus 3 and the RRH 4 to the mobile stationapparatus 5. In the following description, a case where the CRS, theUE-specific RS, and the CSI-RS are respectively used as the first typeof reference signal, the second type of reference signal and the thirdtype of reference signal will be described. In addition, the UE-specificRS may be used in the demodulation of a PDSCH to which the cooperativecommunication is applied and a PDSCH to which the cooperativecommunication is not applied. In addition, the UE-specific RS may beused in the demodulation of a second PDCCH to which the cooperativecommunication (pre-coding process) is applied and a second PDCCH towhich the cooperative communication is not applied.

Signals generated from the control information such as informationindicating the allocation of the DL PRB pair to the PDSCH, informationindicating the allocation of the UL PRB pair to the PUSCH, and a mobilestation identifier (also referred to as a Radio Network TemporaryIdentifier (RNTI)), a modulation scheme, a coding rate, a retransmissionparameter, a spatial multiplexing number, a pre-coding matrix, and aTransmission Power Control command (TPC command) are mapped in the PDCCH(the first PDCCH or the second PDCCH). The control information includedin the PDCCH is referred to as Downlink Control Information (DCI). TheDCI including information indicating allocation of DL PRB pair to thePDSCH is referred to as a downlink assignment (also referred to as DLassignment or Downlink grant), and the DCI including informationindicating allocation of a UL PRB pair to the PUSCH is referred to as auplink grant (also referred to as UL grant). In addition, the downlinkassignment includes a transmission power control command for the PUCCH.In addition, the uplink assignment includes a transmission power controlcommand for the PUSCH. In addition, one PDCCH includes only informationindicating allocation of one PDSCH resource or information indicatingallocation of one PUSCH resource, and does not include informationindicating allocation of resources of a plurality of PDSCHs orinformation indicating allocation of resources of a plurality of PUSCHs.

Further, as information transmitted on the PDCCH, there is a CyclicRedundancy Check (CRC) code. A relationship between the DCI, the RNTI,and CRC which are transmitted on the PDCCH will be described in detail.The CRC code is generated from the DCI using a predetermined generatingpolynomial. A process of an exclusive OR (also referred to as ascrambling) is performed on the generated CRC code using RNTI. Thesignals obtained by modulating a bit indicating the DCI and a bit (alsoreferred to as a CRC masked by UE ID) generated by performing a processof the exclusive OR on the CRC code using RNTI are actually transmittedon the PDCCH.

The PDSCH resource is allocated in the same downlink subframe as thedownlink subframe in which the PDCCH resource including downlinkassignment used in the allocation of the PDSCH resource is allocated, inthe time domain.

The mapping of the downlink reference signal will be described. FIG. 11is a diagram of an example of mapping of the downlink reference signalswithin the downlink subframe of the communication system 1 according toan embodiment of the present invention. For simplicity of description,although the mapping of the downlink reference signals within any one DLPRB pair is described in FIG. 11, an mapping method common to aplurality of DL PRB pairs within the downlink system band is used.

Among shaded downlink resource elements, R0 and R1 indicate the CRSs ofantenna ports 0 and 1, respectively. Here, the antenna port means alogical antenna used in a signal process, and one antenna port may beconfigured with a plurality of physical antennas. With respect to theantenna ports used in transmission of CRS, the plurality of physicalantennas configuring the same antenna port transmit the same signal.With respect to the antenna ports used in transmission of CRS, delaydiversity or Cyclic Delay Diversity (CDD) may be applied using theplurality of physical antennas in the same antenna port, but othersignal processes may not be used. Here, although FIG. 11 shows the casewhere the CRSs correspond to two antenna ports, the communication systemof the present embodiment may correspond to different numbers of antennaports, for example, CRSs for one antenna port or four antenna ports maybe mapped to downlink resources. The CRSs may be allocated within all DLPRB pairs in the downlink system band.

Among shaded downlink resource elements, D1 indicates a downlinkresource element in which UE-specific RS is allocated. Here, the antennaport means a logical antenna used in signal processing, one antenna portmay be configured with a plurality of physical antennas. With respect tothe antenna port used in the transmission of the UE-specific RS, signalssubjected to different signal processes (for example, different phaserotation process) are transmitted through a plurality of physicalantennas configuring the same antenna port. With respect to the antennaport used in the transmission of the UE-specific RS, beamforming isrealized by using a plurality of physical antennas, in the same antennaport. When the UE-specific RS is transmitted by using a plurality ofantenna ports, different codes are used in each antenna port. Forexample, walsh code is used as the code. That is, Code DivisionMultiplexing (CDM) is applied to the UE-specific RS for each antennaport. Here, with respect to the UE-specific RS, the length of code usedin the CDM or the number of the downlink resource elements to be mappedvary depending on the control signal mapped to the DL PRB pair and thetype (the number of antenna ports) of the signal process used in thedata signal.

FIG. 11 illustrates an example of mapping of the UE-specific RS in thecase in which the number of antenna ports used in the transmission ofthe UE-specific RS is one (antenna port 7), or two (antenna port 7 andantenna port 8). For example, when the number of antenna ports used inthe transmission of the UE-specific RS in the base station apparatus 3and the RRH 4 is two, the UE-specific RS is multiplexed and allocated byusing a code of which the code-length is two, with two downlink resourceelements in consecutive time domains (OFDM symbol) in the same frequencydomain (subcarrier) as a unit (a unit of CDM). In other words, in thiscase, CDM is applied to the multiplexing of the UE-specific RS. In FIG.11, the UE-specific RS of the antenna port 7 and the antenna port 8 ismultiplexed by CDM in D1.

FIG. 12 is a diagram illustrating an example of mapping of the downlinkreference signal in the downlink subframe of the communication system 1according to the embodiment of the present invention. Among shadeddownlink resource elements, D1 and D2 indicate UE-specific RS. FIG. 12illustrates an example of mapping of the UE-specific RS in the case inwhich the number of antenna ports used in the transmission of theUE-specific RS is three (antenna port 7, antenna port 8, and antennaport 9), or four (antenna port 7, antenna port 8, antenna port 9, andantenna port 10). For example, when the number of antenna ports used inthe transmission of the UE-specific RS in the base station apparatus 3and the RRH 4 is four, the number of the downlink resource elements towhich the UE-specific RS is mapped is changed to double, and theUE-specific RS is multiplexed to and allocated in different downlinkresource elements for every two antenna ports. In other words, in thiscase, CDM and Frequency Division Multiplexing (FDM) are applied to themultiplexing of the UE-specific RS. In FIG. 12, the UE-specific RS ofthe antenna port 7 and the antenna port 8 is multiplexed by CDM in D1,and the UE-specific RS of the antenna port 9 and the antenna port 10 ismultiplexed by CDM in D2.

For example, when the number of antenna ports used in the transmissionof the UE-specific RS in the base station apparatus 3 and the RRH 4 iseight, the number of the downlink resource elements to which theUE-specific RS is mapped is changed to double, and the UE-specific RS ismultiplexed and allocated by using a code of which the code-length isfour, with four downlink resource elements as a unit. In other words, inthis case, CDMs having different code-lengths are applied to themultiplexing of the UE-specific RS.

Further, in the UE-specific RS, a scramble code is further superimposedon the code of each antenna port. For example, the scramble code isgenerated based on the cell ID (physical cell ID) and the scramble ID,which are notified from the base station apparatus 3 and the RRH 4. Forexample, the scramble code is generated from the pseudo-random sequencegenerated based on the cell ID and the scramble ID, which are notifiedfrom the base station apparatus 3 and the RRH 4. For example, thescramble ID is a value indicating 0 or 1. In addition, parameters passedindividually to each mobile station apparatus 5 may be used in thegeneration of the scrambling codes used for the UE-specific RS. Forexample, each mobile station apparatus 5 is notified of a virtual cellID as a parameter, from the base station apparatus 3. The UE-specific RSis allocated within the DL PRB pair of the PDSCH and the second PDCCHallocated to the mobile station apparatus 5 which is configured to usethe UE-specific RS. Different scrambling methods may be used in theUE-specific RS allocated within the DL PRB pair which is allocated tothe PDSCH and the UE-specific RS allocated within the DL PRB pair whichis allocated to the second PDCCH. For example, with respect to theUE-specific RS allocated within the DL PRB pair which is allocated tothe PDSCH, two virtual cell IDs are configured for the mobile stationapparatus 5 by the base station apparatus 3, and which virtual cell IDis used is indicated by the downlink control information. For example,with respect to the UE-specific RS allocated within the DL PRB pairwhich is allocated to the second PDCCH, one virtual cell ID isconfigured for the mobile station apparatus 5 by the base stationapparatus 3, and the scrambling ID of a fixed value such as 0 is used.

Further, the base station apparatus 3 and the RRH 4 may allocate the CRSsignal to different downlink resource elements, or may allocate the CRSsignal to the same downlink resource element. For example, when the cellIDs notified respectively from the base station apparatus 3 and the RRH4 are different, the CRS signal may be allocated to different downlinkresource elements. In a separate example, only base station apparatus 3may allocate the CRS signal to some downlink resource elements, and theRRH 4 may not allocate the CRS signal to any downlink resource element.For example, when the cell ID is notified only from the base stationapparatus 3, as described above, only the base station apparatus 3 mayallocate the CRS signal to a part of the downlink resource element, andthe RRH 4 may not allocate the CRS signal even to the downlink resourceelement. In a separate example, the base station apparatus 3 and the RRH4 may allocate the CRS signal to the same downlink resource element, andthe base station apparatus 3 and the RRH 4 may transmit the samesequence. For example, when the cell IDs notified from the base stationapparatus 3 and the RRH 4 are the same, the CRS signal may be allocatedas described above.

FIG. 13 is a diagram showing DL PRB pairs to which Channel StateInformation-Reference Signals (CSI-RS) for eight antenna ports aremapped. FIG. 13 shows a case where the CSI-RSs are mapped when thenumber (the number of CSI ports) of antenna ports used in the basestation apparatus 3 and the RRH 4 is eight. In addition, in FIG. 13, thedescriptions about the CRS, the UE-specific RS, the PDCCH, the PDSCH,and the like are omitted for simplicity of explanation.

The orthogonal codes (Walsh code) of two chips are used in each CDMgroups, a CSI port (port of CSI-RS (antenna port, resource grid)) isallocated to each orthogonal code, and the CSI-RS is code divisionmultiplexed for each two CSI port. Further, each CDM groups is frequencydivision multiplexed. By using four CDM groups, the CSI-RSs of eightantenna ports of the CSI ports 1 to 8 (antenna ports 15 to 22) aremapped. For example, in the CDM group C1 of the CSI-RS, the CSI-RSs ofthe CSI ports 1 and 2 (antenna ports 15 and 16) are code divisionmultiplexed and mapped. In the CDM group C2 of the CSI-RS, the CSI-RSsof the CSI ports 3 and 4 (antenna ports 17 and 18) are code divisionmultiplexed and mapped. In the CDM group C3 of the CSI-RS, the CSI-RSsof the CSI ports 5 and 6 (antenna ports 19 and 20) are code divisionmultiplexed and mapped. In the CDM group C4 of the CSI-RS, the CSI-RSsof the CSI ports 7 and 8 (antenna ports 21 and 22) are code divisionmultiplexed and mapped.

When the number of antenna ports of the CSI-RS of the base stationapparatus 3 and the RRH 4 is eight, the base station apparatus 3 and theRRH 4 can configure the number of layers (the number of ranks and aspatial multiplexing number) applied to the PDSCH to eight at maximum.Further, the base station apparatus 3 and the RRH 4 can transmit theCSI-RS when the number of antenna ports of the CSI-RS is 1, 2 or 4. Thebase station apparatus 3 and the RRH 4 can transmit the CSI-RS for oneantenna port or two antenna ports, by using the CDM group C1 of theCSI-RS illustrated in FIG. 13. The base station apparatus 3 and the RRH4 can transmit the CSI-RS for four antenna ports, using the CDM groupsC1 and C2 of the CSI-RS illustrated in FIG. 13.

Further, the base station apparatus 3 and the RRH 4 may allocate theCSI-RSs to different downlink resource elements, respectively, or mayallocate the signal of CSI-RS to the same downlink resource element. Forexample, the base station apparatus 3 and the RRH 4 may allocatedifferent downlink resource elements and/or different signal sequencesto the CSI-RS, respectively. In the mobile station apparatus 5, theCSI-RS transmitted from the base station apparatus 3 and the CSI-RStransmitted from the RRH 4 are recognized as the CSI-RSs respectivelycorresponding to different antenna ports. The configuration (the numberof antenna ports, resource location, and subframe to be transmitted) ofthe CSI-RS transmitted from the base station apparatus 3 and theconfiguration of CSI-RS transmitted from the RRH 4 are separatelyconfigured for the mobile station apparatus 5. Further, theconfiguration of CSI-RS transmitted from a plurality of RRHs 4 may berespectively and separately set for the mobile station apparatus 5.

The configuration of the CSI-RS (CSI-RS-Config-r10) is notified from thebase station apparatus 3 and the RRH 4 to the mobile station apparatus5. For example, the configuration of the CSI-RS includes at leastinformation (antennaPortsCount-r10) indicating the number of antennaports which are configured for the CSI-RS, information(subframeConfig-r10) indicating downlink subframes allocated for theCSI-RS, and information (ResourceConfig-r10) indicating the frequencydomain for which the CSI-RS is allocated. The number of antenna ports ofthe CSI-RS may be, for example, any value of 1, 2, 4, and 8. Asinformation indicating a frequency domain to which the CSI-RS isallocated, an index indicating a position of the first resource elementamong resource elements in which the CSI-RS corresponding to the antennaport 15 (CSI port 1) is used. If the position of the CSI-RScorresponding to the antenna port 15 is decided, the CSI-RSscorresponding to other antenna ports are uniquely decided based on thepredetermined rule. As information indicating a downlink subframe inwhich the CSI-RS is allocated, the position and the period of thedownlink subframe in which the CSI-RS is allocated are indicated by anindex. For example, if the index of the subframeConfig-r10 is 5, theindex indicates that the CSI-RS is allocated at every 10 subframes andthe CSI-RS is allocated in the subframe 0 (the subframe number in theradio frame) among a radio frame with 10 subframes as a unit. Further,in a separate example, for example, if the index of thesubframeConfig-r10 is 1, the index indicates that the CSI-RS isallocated at every five subframes and the CSI-RS is allocated in thesubframes 1 and 6 among a radio frame with 10 subframes as a unit.

<Configuration of Uplink Time Frame>

FIG. 14 is a diagram showing a schematic configuration of the uplinktime frame from the mobile station apparatus 5 to the base stationapparatus 3 and the RRH 4, according to the embodiment of the presentinvention. In FIG. 13, the horizontal axis represents a time domain andthe vertical axis represents a frequency domain. The uplink time frameis a unit of allocation of a resource and the like, and is configuredwith pairs (also referred to as an UpLink Physical Resource Block pair(UL PRB pair)) of Physical Resource Blocks (RB) (PRB) configured withthe frequency band and the time band of a predetermined width of theuplink. One UL PRB pair is configured with two consecutive uplink PRBsin the time domain in the uplink (also referred to as an UpLink PhysicalResource Block (UL PRB)).

Further, in FIG. 14, one UL PRB is configured with 12 subcarriers in thefrequency domain in the uplink (also referred to as a uplink subcarrier)and seven Single-Carrier Frequency Division Multiple access (SC-FDMA)symbols in the time domain. A system band of the uplink (referred to asan uplink system band) is uplink communication bands of the base stationapparatus 3 and the RRH 4. For example, a system bandwidth of the uplink(referred to as an uplink system bandwidth) is configured with afrequency bandwidth of 20 MHz.

In addition, a plurality of UL PRB pairs are allocated in the uplinksystem band according to the uplink system bandwidth. For example, theuplink system band of a frequency bandwidth of 20 MHz is configured with110 UL PRB pairs. Further, in the time domain illustrated in FIG. 14,there are a slot (referred to as an uplink slot) configured with sevenSC-FDMA symbols, and a subframe (referred to as an uplink subframe)configured with two uplink slots. In addition, a unit configured withone uplink subcarrier and one SC-FDMA symbol is referred to as aresource element (referred to as an uplink resource element).

At least the PUSCH used in transmission of information data, the PUCCHused in transmission of the uplink Control Information (UCI), and the ULRS (DM RS) for demodulation (channel change estimation) of the PUSCH andthe PUCCH are allocated in each uplink subframe. Further, although notshown, the PRACH used for synchronization establishment of the uplink isallocated in any uplink subframe. Further, although not shown, the UL RS(SRS) used in measurement of channel quality and synchronizationdeviation, and the like is allocated in any uplink subframe. The PUCCHis used for transmitting a UCI (ACK/NACK) indicating Acknowledgement(ACK) or Negative Acknowledgement (NACK) for data received using thePDSCH, a UCI (SR: Scheduling Request) indicating at least whether arequest for the uplink resource allocation is made or not, and a UCI(CQI: Channel Quality Indicator) indicating reception quality of thedownlink (also referred to as channel quality).

In addition, when the mobile station apparatus 5 indicates to the basestation apparatus 3 that it makes a request for uplink resourceallocation, the mobile station apparatus 5 transmits signals on thePUCCH for transmission of the SR. The base station apparatus 3recognizes that the mobile station apparatus 5 makes a request for theuplink resource allocation, from the result in which signals aredetected on the PUCCH resource for transmission of the SR. When themobile station apparatus 5 indicates to the base station apparatus 3that it does not make a request for uplink resource allocation, themobile station apparatus 5 does not transmit any signals on thepre-allocated PUCCH resource for transmission of the SR. The basestation apparatus 3 recognizes that the mobile station apparatus 5 doesnot make a request for the uplink resource allocation, from the resultin which signals are not detected on the PUCCH resource for transmissionof the SR.

Further, different types of signal configurations are used for the PUCCHin a case where the UCI configured with ACK/NACK is transmitted, a casewhere the UCI configured with the SR is transmitted, and a case wherethe UCI configured with the CQI is transmitted. The PUCCH used in thetransmission of the ACK/NACK is referred to as a PUCCH format 1a or aPUCCH format 1b. In the PUCCH format 1a, Binary Phase Shift Keying (BPSK) is used as a modulation scheme of modulation information regardingthe ACK/NACK. In the PUCCH format 1a, one bit of information isrepresented from a modulation signal. In the PUCCH format 1b, QuadraturePhase Shift Keying (QPSK) is used as a modulation scheme of modulationinformation regarding the ACK/NACK. In the PUCCH format 1b, two bits ofinformation are represented from a modulation signal. The PUCCH used inthe transmission of the SR is referred to as a PUCCH format 1. The PUCCHused in the transmission of CQI is referred to as a PUCCH format 2. ThePUCCH used in the simultaneous transmission of the CQI and the ACK/NACKis referred to as a PUCCH format 2a or a PUCCH format 2b. In the PUCCHformat 2a and the PUCCH format 2b, a reference signal (DM RS) of anuplink pilot channel is multiplied by a modulation signal generated fromthe ACK/NACK information. In the PUCCH format 2a, one bit of informationregarding the ACK/NACK and information of CQI are transmitted. In thePUCCH format 2b, two-bit information regarding the ACK/NACK andinformation of CQI are transmitted.

In addition, one PUSCH is configured with one or more UL PRB pairs, onePUCCH is in a symmetrical relationship with the frequency domain in theuplink system band, and configured with two UL PRBs located in differentuplink slots, and one PRACH is configured with six UL PRB pairs. Forexample, in FIG. 14, one UL PRB pair used in the PUCCH is configuredwith the UL PRB having the lowest frequency in the first uplink slot andthe UL PRB having the highest frequency in the second uplink slot withinthe uplink subframe. Further, if it is configured such that simultaneoustransmission of the PUSCH and the PUCCH is not performed, when the PUCCHresource and the PUSCH resource are allocated in the same uplinksubframe, the mobile station apparatus 5 transmits signals using onlythe PUSCH resource. Furthermore, if it is configured such thatsimultaneous transmission of the PUSCH and the PUCCH is performed, whenthe PUCCH resource and the PUSCH resource are allocated in the sameuplink subframe, the mobile station apparatus 5 may transmit signals byusing both the PUCCH resource and the PUSCH resource, basically.

The UL RS is a signal used in the uplink pilot channel. The UL RS isconfigured with a DeModulation Reference Signal (DM RS) used in theestimation of the channel of the PUSCH and the PUCCH and a SoundingReference Signal (SRS) used in the measurement of the channel qualityfor frequency scheduling and the adaptive modulation of the PUSCH of thebase station apparatus 3 and the RRH 4 and the measurement of thesynchronization deviation between the base station apparatus 3, the RRH4 and the mobile station apparatus 5. In addition, for simplicity ofexplanation, the SRS is not illustrated in FIG. 14. When the DM RS isallocated in the same UL PRB as in the PUSCH and is allocated in thesame UL PRB as in the PUCCH, the DM RS is allocated in different SC-FDMAsymbols. The DM RS is a known signal in the communication system 1 whichis used in the estimation of the channel change of the PUSCH and thePUCCH.

When the DM RS is allocated in the same UL PRB as in the PUSCH, it isallocated in the fourth SC-FDMA symbol within the uplink slot. When theDM RS is allocated within the same UL PRB as the PUCCH includingACK/NACK, it is allocated in the third, fourth and fifth SC-FDMA symbolswithin the uplink slot. When the DM RS is allocated in the same UL PRBas the PUCCH including the SR, it is allocated in the third, fourth andfifth SC-FDMA symbols within the uplink slot. When the DM RS isallocated within the same UL PRB as the PUCCH including the CQI, it isallocated in the second and sixth SC-FDMA symbols within the uplinkslot.

The SRS is allocated within the UL PRB decided by the base stationapparatus 3, and allocated in the 14th SC-FDMA symbol within the uplinksubframe (the seventh SC-FDMA symbol of the second uplink slot in theuplink subframe). The SRS may be allocated only in the uplink subframeof a period decided by the base station apparatus 3 (also referred to asa Search Reference Signal subframe; SRS subframe)) in the cell. The basestation apparatus 3 allocates a period of transmitting a SRS for everymobile station apparatus 5 and UL PRB allocated to the SRS in the SRSsubframe.

Although FIG. 14 shows a case where the PUCCHs are allocated in the ULPRB nearest the edge in the frequency domain of the uplink system band,the second and third UL PRBs from the edge of the uplink system band maybe used for the PUCCH.

In addition, a code multiplexing in the frequency domain and a codemultiplexing in the time domain are used in the PUCCH. The codemultiplexing in the frequency domain is processed by multiplying amodulation signal obtained through modulation of the uplink controlinformation and each code of a code sequence in a unit of a subcarrier.The code multiplexing in the time domain is processed by multiplying amodulation signal obtained through modulation of the uplink controlinformation and each code of a code sequence in a unit of a SC-FDMAsymbol. A plurality of PUCCHs are allocated in the same UL PRB,different codes are allocated to respective PUCCHs, and the codemultiplexing in the frequency domain or the time domain is realized bythe allocated codes. The code multiplexing in the frequency domain andthe time domain is used in the PUCCH (referred to as a PUCCH format 1aor a PUCCH format 1b) used for transmitting an ACK/NACK. The codemultiplexing in the frequency domain and the time domain is used in thePUCCH (referred to as the PUCCH format 1) used for transmitting the SR.The code multiplexing in the frequency domain is used in the PUCCH(referred to as a PUCCH format 2, a PUCCH format 2a or a PUCCH format2b) used for transmitting the CQI.

FIG. 15 is a diagram illustrating the configuration and the number ofACK/NACK PUCCH resource in the communication system according to theembodiment of the present invention. Here, FIG. 15 illustrates anexample of the PUCCH resource for which the PUCCH format 1a or the PUCCHformat 1b is used. FIG. 15 illustrates the case in which the 24 PUCCHresources for ACK/NACK are configured in each uplink subframe. Further,FIG. 15 illustrates the case in which two UL PRB pairs (a UL PRB pair 5and a UL PRB pair 6), four code sequences in the frequency domain (codesin the frequency domain) (a code 1 in the frequency domain, a code 2 inthe frequency domain, a code 3 in the frequency domain, and a code 4 inthe frequency domain), three code sequences in the time domain (codes inthe time domain) (a code 1 in the time domain, a code 2 in the timedomain, and a code 3 in the time domain) are used in the ACK/NACK PUCCHresource. The UL PRB pairs, the code sequences in the frequency domain,and the code sequences in the time domain of the number different fromthe number illustrated in FIG. 15 may be used, and the PUCCH resource ofthe number different from the number illustrated in FIG. 15 may beconfigured. Respective PUCCH resources illustrated in FIG. 15 areconfigured with different combinations of the UL PRB pair, the codesequence in the frequency domain, and the code sequence in the timedomain, and are orthogonal in the frequency domain, the code region inthe frequency domain, or the code region in the time domain. Differentnumbering (PUCCH resource index) is performed on the PUCCH resourcesconfigured with different combinations of the UL PRB pair, the codesequence in the frequency domain, and the code sequence in the timedomain.

Note that in FIG. 15, frequency hopping between slots applied to thePUCCH is not described for simplification of explanation. For example,FIG. 15 illustrates a configuration of resource of a first uplink slotof the uplink subframe, and UL PRB resource which is an object in thefrequency domain in the uplink system band is configured in a seconduplink slot of the uplink subframe. For example, in the uplink systemband configured with 110 UL PRB pairs, the PUCCH 1 is configured withthe UL PRB of a UL PRB pair 105, the code 1 in the frequency domain, andthe code 1 in the time domain in the second uplink slot of the uplinksubframe. Further, sequence hopping may be applied to the code sequencein the frequency domain configured with the first uplink slot of theuplink subframe and the code sequence in the frequency domain configuredwith the second uplink slot of the uplink subframe. Further, sequencehopping may be applied to the code sequence in the time domainconfigured with the first uplink slot of the uplink subframe and thecode sequence in the time domain configured with the second uplink slotof the uplink subframe.

In the time domain, the PUSCH resource is allocated in the uplinksubframe after a predetermined number (for example, four) from thedownlink subframe in which the PDCCH resource including the uplink grantused in the allocation of the PUSCH resource is allocated.

The PDSCH resource is mapped in the same downlink subframe as thedownlink subframe in which the PDCCH resource including a downlinkassignment used in the allocation of the PDSCH resource is mapped, inthe time domain.

<Configuration of First PDCCH>

The first PDCCH is configured with a plurality of Control ChannelElements (CCE). The number of CCEs used in each downlink system banddepends on the downlink system bandwidth, the number of OFDM symbolsconfiguring the first PDCCH, and the number of the downlink referencesignals of the downlink pilot channel (CRS) according to the number ofthe transmit antennas of the base station apparatus 3 (or the RRH 4)used in the communication. As described below, the CCE is configuredwith a plurality of the downlink resource elements.

FIG. 16 is a diagram illustrating a logical relationship between thefirst PDCCH and the CCE of the communication system 1 according to theembodiment of the present invention. The numbers for identifying CCEsare given to the CCEs used between the base station apparatus 3 (or theRRH 4) and the mobile station apparatus 5. The CCE numbering isperformed on the basis of a predetermined rule. Here, CCE t indicatesthe CCE of the CCE number t. The first PDCCH is configured with anaggregation formed of a plurality of CCEs (CCE Aggregation).Hereinafter, the number of CCEs configuring an aggregation is referredto as “CCE aggregation number” (CCE aggregation level). The CCEaggregation number configuring the first PDCCH is configured accordingto a coding rate which is configured in the first PDCCH and the numberof bits of the DCI included in the first PDCCH by the base stationapparatus 3. Further, hereinafter, the aggregation configured with nCCEs is referred to as “CCE aggregation n”.

For example, the base station apparatus 3 configures the first PDCCHwith one CCE (CCE aggregation1), configures the first PDCCH with twoCCEs (CCE aggregation2), configures the first PDCCH with four CCEs (CCEaggregation4), and configures the first PDCCH with eight CCEs (CCEaggregation8). For example, the base station apparatus 3 uses the CCEaggregation number having a small number of CCEs for use in configuringthe first PDCCH for the mobile station apparatus 3 having a good channelquality, and uses the CCE aggregation number having a great number ofCCEs for use in configuring the first PDCCH for the mobile stationapparatus 3 having a bad channel quality. Further, for example, when thebase station apparatus 3 transmits DCI having a small number of bits,the base station apparatus 3 uses the CCE aggregation number having asmall number of CCEs for use in configuring the first PDCCH, and whenthe base station apparatus 3 transmits DCI having a great number ofbits, the base station apparatus 3 uses the CCE aggregation numberhaving a great number of CCEs for use in configuring the first PDCCH.

In FIG. 16, those represented by the diagonal lines mean first PDCCHcandidates. The first PDCCH candidates are to be subjected to a decodingdetection of the first PDCCH by the mobile station apparatus 5, and thefirst PDCCH candidates are configured independently for each CCEaggregation number. The first PDCCH candidates configured for each CCEaggregation number are respectively configured with different one ormore CCEs. The number of the first PDCCH candidates is configuredindependently for each CCE aggregation number. The first PDCCHcandidates configured for each CCE aggregation number are configuredwith consecutive numbers of CCEs. The mobile station apparatus 5performs a decoding detection of the first PDCCH on the first PDCCHcandidates of the number which is configured for each CCE aggregationnumber. In addition, when the mobile station apparatus 5 determines thatthe first PDCCH addressed to the mobile station apparatus 5 is detected,the mobile station apparatus 5 may not perform (may stop) the decodingdetection of the first PDCCH for some first PDCCH candidates which areconfigured.

A plurality of downlink resource elements configuring the CCE areconfigured with a plurality of resource element groups (also referred toas a REG, mini-CCE). The resource element group is configured with aplurality of the downlink resource elements. For example, one resourceelement group is configured with four downlink resource elements. FIG.17 is a diagram showing an example of mapping of a resource elementgroup in a downlink subframe of the communication system 1 according tothe embodiment of the present invention. Here, the resource elementgroup used in the first PDCCH is shown, and the portions that are notrelated (PDSCH, second PDCCH, UE-specific RS, and CSI-RS) are neithershown nor described. Here, a case where the first PDCCH is configuredwith the first to third OFDM symbols and the downlink reference signals(R0 and R1) corresponding to the CRS of two transmit antennas (antennaport 0 and antenna port 1) are shown. In FIG. 17, the vertical axisrepresents a frequency domain and the horizontal axis represents a timedomain.

In the mapping example of FIG. 17, one resource element group isconfigured with four adjacent downlink resource elements in thefrequency domain. FIG. 17 shows that the downlink resource elementshaving the same code of the first PDCCH attached therein belong to thesame resource element group. In addition, the resource element group isconfigured while the resource elements R0 (downlink reference signal ofthe antenna port 0) and R1 (downlink reference signal of the antennaport 1) in which the downlink reference signals are allocated areskipped. FIG. 17 shows that numbering (code “1”) is performed from aresource element group of the first OFDM symbols having the lowestfrequency, numbering (code “2”) is subsequently performed for a resourceelement group of the second OFDM symbols having the lowest frequency,and numbering (code “3”) is subsequently performed for a resourceelement group of the third OFDM symbols having the lowest frequency.FIG. 17 shows that numbering (code “4”) is subsequently performed for aresource element group of the second OFDM symbols, in which the downlinkreference signals are not allocated, adjacent to the frequency of theresource element group subjected to the numbering (code “2”), andnumbering (code “5”) is subsequently performed for a resource elementgroup of the third OFDM symbols, in which the downlink reference signalsare not allocated, adjacent to the frequency of the resource elementgroup subjected to the numbering (code “3”). FIG. 17 shows thatnumbering (code “6”) is subsequently performed for a resource elementgroup of the first OFDM symbols adjacent to the frequency of theresource element group subjected to the numbering (code “1”), numbering(code “7”) is subsequently performed for a resource element group of thesecond OFDM symbols adjacent to the frequency of the resource elementgroup subjected to the numbering (code “4”), and numbering (code “8”) issubsequently performed for a resource element group of the third OFDMsymbols adjacent to the frequency of the resource element groupsubjected to the numbering (code “5”). The same numbering is performedfor the following resource element groups.

The CCE is configured with a plurality of resource element groupsillustrated in FIG. 17. For example, one CCE is configured with ninedifferent resource element groups which are Distributed in the frequencydomain and the time domain. Specifically, in the CCEs used in the firstPDCCH, all resource element groups subjected to the numbering asillustrated in FIG. 17 are subjected to interleaving in units ofresource element groups using a block interleaver for all downlinksystem bands, and one CCE is configured with nine resource elementgroups of consecutive numbers after being interleaved.

<Configuration of Second PDCCH>

A region in which a second PDCCH may be mapped (for simplicity ofexplanation, hereinafter, referred to as a second PDCCH region) (ePDCCHregion) is configured (set) for the mobile station apparatus 5. The unitof mapping of resource configuring one second PDCCH is a set of DL PRBpairs of a predetermined number, and is one second PDCCH region. One ormore second PDCCH regions may be configured for the mobile stationapparatus 5. For example, in a plurality of mobile station apparatuses 5in which a plurality of second PDCCH regions are configured, some secondPDCCH regions can be configured with a plurality of common DL PRB pairs,and another part of the second PDCCH regions can be configured with aplurality of different DL PRB pairs. The mobile station apparatus 5performs a decoding process for detecting the second PDCCH, in each ofthe plurality of configured second PDCCH regions. In addition, thesecond PDCCH region may be referred to as an enhanced Physical DownlinkControl Channel Set (ePDCCH set).

FIG. 18 is a diagram illustrating an example of a schematicconfiguration of the second PDCCH region in the communication system 1according to an embodiment of the present invention. The base stationapparatus 3 can configure (set, arrange) a plurality of second PDCCHregions (a second PDCCH region 1, a second PDCCH region 2, and a secondPDCCH region 3) in a downlink system band. One second PDCCH region isconfigured with a plurality of DL PRB pairs. For example, one secondPDCCH region is configured with four DL PRB pairs. For example, aplurality of DL PRB pairs configuring one second PDCCH region may beconfigured with the DL PRB pairs which are distributed in the frequencydomain as illustrated in FIG. 18, and may be configured with the DL PRBpairs which are consecutive in the frequency domain. For example, thebase station apparatus 3 can configure the second PDCCH region for eachof a plurality of mobile station apparatuses 5. In FIG. 18, the secondPDCCH region 1, the second PDCCH region 2, and the second PDCCH region 3are respectively configured with different DL PRB pairs.

With respect to each of the second PDCCH regions which are configured inthe mobile station apparatus 5, different transmission methods may beset in signals to be mapped. For example, a beamforming process suitablefor the mobile station apparatus 5 is applied to a certain second PDCCHregion which is configured in the mobile station apparatus 5. Forexample, a random beamforming process is applied to a certain secondPDCCH region which is configured in the mobile station apparatus 5.Here, the beamforming process suitable for the mobile station apparatus5 means that an optimal pre-coding process is performed based on thechannel state information (Precoding Matrix Indicator: PMI) notifiedfrom the mobile station apparatus 5 to the base station apparatus 3.Here, the random beamforming process means that a randomly selectedpre-coding process (a process in which a pre-coding matrix is randomlyselected and multiplied in a signal) is performed on the resource ofeach DL PRB pair configuring one second PDCCH. For example, thebeamforming process that is suitable for the mobile station apparatus 5is applied to a mobile station apparatus 5 which slowly moves and ofwhich the channel state information is fed back to the base stationapparatus 3 as appropriate. For example, the random beamforming processis applied to a mobile station apparatus 5 which moves fast and of whichthe channel state information is not fed back to the base stationapparatus 3 as appropriate. In the second PDCCH in which the beamformingprocess that is suitable for the mobile station apparatus 5 isperformed, the same pre-coding process is performed on all signalstransmitted in the second PDCCH. In the second PDCCH in which the randombeamforming process is performed, the same pre-coding process is notperformed on all signals transmitted in the second PDCCH and a differentpre-coding process is performed on the different signals. For example,in the second PDCCH in which the random beamforming process isperformed, a different pre-coding process is performed on the signalsmapped in the different DL PRB pairs. Preferably, in the second PDCCH inwhich the random beamforming process is performed, pre-coding matrixesthat are orthogonal with each other are used for signals mapped in thedifferent DL PRB pairs.

In the DL PRB pair, the same pre-coding process is applied to the secondPDCCH signal and the UE-specific RS which are transmitted to the samemobile station apparatus 5. In the DL PRB pair in which signals of thesecond PDCCH to be subjected to the beamforming process suitable for themobile station apparatus are mapped, different pre-coding processes maybe performed for different second PDCCH signals for different mobilestation apparatuses 5. In DL PRB pair in which signals of the secondPDCCH to be subjected to the random beamforming process are mapped, thesame pre-coding process may be performed for different second PDCCHsignals for different mobile station apparatuses 5.

One second PDCCH is configured with one or more eCCEs (second element).FIG. 19 is a diagram illustrating a logical relationship between thesecond PDCCH and the eCCE of the communication system 1 according to theembodiment of the present invention. The numbers for identifying E-CCEsare given to the eCCEs used between the base station apparatus 3 (or theRRH 4) and the mobile station apparatus 5. The eCCE numbering isperformed based on predetermined rules. Here, eCCE t indicates the eCCEof the eCCE number t. The second PDCCH is configured with an aggregationconfigured with a plurality of eCCEs (eCCE aggregation). Hereinafter,the number of eCCEs configuring the aggregation is referred to as “eCCEaggregation number” (eCCE aggregation level). For example, the eCCEaggregation number configuring the second PDCCH is configured accordingto a coding rate which is configured in the second PDCCH and the numberof bits of the DCI included in the second PDCCH in the base stationapparatus 3. Further, hereinafter, the aggregation configured with neCCEs is referred to as “eCCE aggregation n”.

For example, the base station apparatus 3 configures the second PDCCHwith one eCCE (eCCE aggregation1), configures the second PDCCH with twoeCCEs (eCCE aggregation2), configures the second PDCCH with four eCCEs(eCCE aggregation4), and configures the second PDCCH with eight eCCEs(eCCE aggregation8). For example, the base station apparatus 3 uses theeCCE aggregation number having a small number of eCCEs for use inconfiguring the second PDCCH for the mobile station apparatus 3 having agood channel quality, and uses the eCCE aggregation number having agreat number of eCCEs for use in configuring the second PDCCH for themobile station apparatus 3 having a bad channel quality. Further, forexample, when the base station apparatus 3 transmits a DCI having asmall number of bits, the base station apparatus 3 uses the eCCEaggregation number having a small number of eCCEs for use in configuringthe second PDCCH, and when the base station apparatus 3 transmits a DCIhaving a large number of bits, the base station apparatus 3 uses theeCCE aggregation number having a great number of eCCEs for use inconfiguring the second PDCCH.

In FIG. 19, those represented by the diagonal lines mean second PDCCHcandidates. The second ePDCCH candidates are to be subjected to thedecoding detection of the second PDCCH by the mobile station apparatus5, and the second PDCCH candidates are configured independently for eacheCCE aggregation number. The second PDCCH candidates configured for eacheCCE aggregation number are respectively configured with different oneor more VRBs. The number of the second PDCCH candidates is configuredindependently for each eCCE aggregation number. The second PDCCHcandidates configured for each eCCE aggregation number are configuredwith consecutive numbers of eCCEs. The mobile station apparatus 5performs a decoding detection of the second PDCCH on the second PDCCHcandidates of the number which is configured for each VRB aggregationnumber. In addition, when the mobile station apparatus 5 determines thatit detects the second PDCCH addressed to the mobile station apparatus 5,the decoding detection of the second PDCCH may not be performed (may bestopped) for some second PDCCH candidates which are configured.

The number of eCCEs configured in one second PDCCH region depends on thenumber of DL PRB pairs configuring the second PDCCH region. For example,the amount of resources corresponding to one eCCE (the number ofresource elements) is substantially equal to the amount of resourcesobtained by removing resources that cannot be used for the signals ofthe second PDCCH (resource elements used in the downlink referencesignal and the first PDCCH), from four resources into which the resourceof one DL PRB pair is divided. For example, 16 eCCEs are configured inthe second PDCCH region configured with four DL PRB pairs. Further, inthe embodiment of the present invention, for simplicity of explanation,a description has been mainly made of the case in which one second PDCCHregion is configured with four DL PRB pairs and 16 eCCEs are configuredin one second PDCCH region, but the present invention is not limited tosuch a case. For example, one second PDCCH region may be configured withDL PRB pairs of the number other than four. For example, the amount ofresources corresponding to one eCCE (the number of resource elements)may be the amount different from the amount of resources obtained byremoving resources that cannot be used for the signals of the secondPDCCH (resource elements used in the downlink reference signal and thefirst PDCCH), from four resources into which the resource of one DL PRBpair is divided, and may be substantially equal to the amount ofresources obtained by removing resources that cannot be used for thesignals of the second PDCCH (resource elements used in the downlinkreference signal and the first PDCCH), from two resources into which theresource of one DL PRB pair is divided.

Two types of methods are used as a mapping method of resourcesconfiguring the second PDCCH. For convenience of explanation, themethods are referred to as a Localized mapping (a first mapping method)and a Distributed mapping (a second mapping method). The transmission ofthe second PDCCH using the resources configured by the Localized mappingis referred to as Localized transmission. The transmission of the secondPDCCH using the resources configured by the Distributed mapping isreferred to as Distributed transmission. For example, a beamformingprocess suitable for the mobile station apparatus 5 is applied to theLocalized transmission. For example, the random beamforming processdescribed above is applied to the Distributed transmission. TheLocalized mapping is a method in which one eCCE is mapped to resourcesin one DL PRB pair. The Distributed mapping is a method in which oneeCCE is mapped to resources in a plurality of DL PRB pairs. For example,in the Distributed mapping, one eCCE is mapped to some resources in eachof four DL PRB pairs of the second PDCCH region. In other words, in theLocalized mapping, one eCCE is configured with physical resources in oneDL PRB pair. In the Distributed mapping, one eCCE is configured withsome resources in each of the plurality of DL PRB pairs.

FIG. 20 is a diagram illustrating an example of the Localized mapping ofthe embodiment of the present invention. Here, the case is illustratedin which one second PDCCH region is configured with four DL PRB pairs,four eCCEs are configured in one DL PRB pair, and 16 eCCEs (eCCE1,eCCE2, eCCE3, eCCE4, eCCE5, eCCE6, eCCE7, eCCE8, eCCE9, eCCE10, eCCE11,eCCE12, eCCE13, eCCE14, eCCE15, and eCCE16) are configured in one secondPDCCH region. For example, in FIG. 20, each DL PRB pair corresponds toeach DL PRB pair configuring the second PDCCH region in FIG. 18. In FIG.20, one mass (a mass configured with four eCCEs of consecutive numbers)(a mass configured with eCCE1, eCCE2, eCCE3, and eCCE4, a massconfigured with eCCE5, eCCE6, eCCE7, and eCCE8, a mass configured witheCCE9, eCCE10, eCCE11, and eCCE12, and a mass configured with eCCE13,eCCE14, eCCE15, and eCCE16) means resources of one DL PRB pair. Further,in FIG. 20, physically, the horizontal axis does not mean a frequencydomain and the vertical axis does not mean a time domain. FIG. 20conceptually represents that one DL PRB pair is divided into fourresources and one eCCE is configured with the divided resources.Further, FIG. 20 does not mean that all resources in the DL PRB pair areconfigured with eCCEs, and for example, the resource in which theUE-specific RS is allocated may be excluded in advance from theresources configuring the eCCE. A physical resource configuring one eCCEwhich has been configured by employing the Localized mapping will bedescribed later.

FIG. 21 is a diagram illustrating an example of the Distributed mappingof the embodiment of the present invention. Here, the case isillustrated in which one second PDCCH region is configured with four DLPRB pairs (a DL PRB pair W, a DL PRB pair X, a DL PRB pair Y, and a DLPRB pair Z), 16 eREGs (enhanced Resource Element Group) (eREG1, eREG2,eREG3, eREG4, eREG5, eREG6, eREG7, eREG8, eREG9, eREG10, eREG11, eREG12,eREG13, eREG14, eREG15, and eREG16) are configured in one DL PRB pair,and 16 eCCEs (eCCE1, eCCE2, eCCE3, eCCE4, eCCE5, eCCE6, eCCE7, eCCE8,eCCE9, eCCE10, eCCE11, eCCE12, eCCE13, eCCE14, eCCE15, and eCCE16) areconfigured in one second PDCCH region. Here, eREG (first element) is anelement having a smaller amount of resources that that of the eCCE, andone eCCE is configured with a plurality of eREGs. For example, one eCCEis configured with four eREGs. For example, in FIG. 21, each DL PRB paircorresponds to each DL PRB pair configuring the second PDCCH regionillustrated in FIG. 18. Each eCCE is configured by arranging a pluralityof eREGs of a different DL PRB pair. For example, the eCCE is four eREGsof four DL PRB pairs, and is configured with resources obtained bycollecting one eREG from each DL PRB pair.

In FIG. 21, eCCE1 is configured with eREG1 of a DL PRB pair W, eREG1 ofa DL PRB pair X, eREG1 of a DL PRB pair Y, and eREG1 of a DL PRB pair Z,eCCE2 is configured with eREG2 of a DL PRB pair W, eREG2 of a DL PRBpair X, eREG2 of a DL PRB pair Y, and eREG2 of a DL PRB pair Z, eCCE3 isconfigured with eREG3 of a DL PRB pair W, eREG3 of a DL PRB pair X,eREG3 of a DL PRB pair Y, and eREG3 of a DL PRB pair Z, and the eCCE4 isconfigured with eREG4 of a DL PRB pair W, eREG4 of a DL PRB pair X,eREG4 of a DL PRB pair Y, and eREG4 of a DL PRB pair Z, eCCE5 isconfigured with eREG5 of a DL PRB pair W, eREG5 of a DL PRB pair X,eREG5 of a DL PRB pair Y, and eREG5 of a DL PRB pair Z, eCCE6 isconfigured with eREG6 of a DL PRB pair W, eREG6 of a DL PRB pair X,eREG6 of a DL PRB pair Y, and eREG6 of a DL PRB pair Z, eCCE7 isconfigured with eREG7 of a DL PRB pair W, eREG7 of a DL PRB pair X,eREG7 of a DL PRB pair Y, and eREG7 of a DL PRB pair Z, eCCE8 isconfigured with eREG8 of a DL PRB pair W, eREG8 of a DL PRB pair X,eREG8 of a DL PRB pair Y, and eREG8 of a DL PRB pair Z, eCCE9 isconfigured with eREG9 of a DL PRB pair W, eREG9 of a DL PRB pair X,eREG9 of a DL PRB pair Y, and eREG9 of a DL PRB pair Z, eCCE10 isconfigured with eREG10 of a DL PRB pair W, eREG10 of a DL PRB pair X,eREG10 of a DL PRB pair Y, and eREG10 of a DL PRB pair Z, eCCE11 isconfigured with eREG11 of a DL PRB pair W, eREG11 of a DL PRB pair X,eREG11 of a DL PRB pair Y, and eREG11 of a DL PRB pair Z, eCCE12 isconfigured with eREG12 of a DL PRB pair W, eREG12 of a DL PRB pair X,eREG12 of a DL PRB pair Y, and eREG12 of a DL PRB pair Z, eCCE13 isconfigured with eREG13 of a DL PRB pair W, eREG3 of a DL PRB pair X,eREG13 of a DL PRB pair Y, and eREG13 of a DL PRB pair Z, eCCE14 isconfigured with eREG14 of a DL PRB pair W, eREG14 of a DL PRB pair X,eREG14 of a DL PRB pair Y, and eREG14 of a DL PRB pair Z, eCCE15 isconfigured with eREG15 of a DL PRB pair W, eREG15 of a DL PRB pair X,eREG15 of a DL PRB pair Y, and eREG15 of a DL PRB pair Z, and the eCCE16is configured with eREG16 of a DL PRB pair W, eREG16 of a DL PRB pair X,eREG16 of a DL PRB pair Y, and eREG16 of a DL PRB pair Z.

Further, in FIG. 21, physically, the horizontal axis does not mean afrequency domain and the vertical axis does not mean a time domain, butconceptually represents that one DL PRB pair is divided into 16resources and one eCCE is configured with four divided resources of fourdifferent DL PRB pairs. Further, FIG. 21 does not mean that allresources in the DL PRB pair are configured with eREGs, and for example,the resource in which the UE-specific RS is allocated may be excluded inadvance from the resources configuring the eREG The physical resourcesconfiguring one eREG which has been configured by employing theDistributed mapping will be described later.

Further, the eCCE which has been configured by employing the Localizedmapping may be configured by using the eREG illustrated in FIG. 21. TheeCCE which has been configured by employing the Localized mapping isconfigured with four eREGs in one DL PRB pair. For example, the numbersof the eREGs configuring the eCCE which has been configured by employingthe Localized mapping are consecutive. With respect to the eCCEs (eCCE1,eCCE2, eCCE3, eCCE4, eCCE5, eCCE6, eCCE7, eCCE8, eCCE9, eCCE10, eCCE11,eCCE12, eCCE13, eCCE14, eCCE15, and eCCE16) which have been configuredby employing the Localized mapping illustrated in FIG. 20, the eCCE1 isconfigured with eREG1, eREG2, eREG3, and eREG4 of the DL PRB pair Willustrated in FIG. 21, the eCCE2 is configured with eREG5, eREG6,eREG7, and eREG8 of the DL PRB pair W illustrated in FIG. 21, the eCCE3is configured with eREG9, eREG10, eREG11, and eREG12 of the DL PRB pairW illustrated in FIG. 21, the eCCE4 is configured with eREG13, eREG14,eREG15, and eREG16 of the DL PRB pair W illustrated in FIG. 21, theeCCE5 is configured with eREG1, eREG2, eREG3, and eREG4 of the DL PRBpair X illustrated in FIG. 21, the eCCE6 is configured with eREG5,eREG6, eREG7, and eREG8 of the DL PRB pair X illustrated in FIG. 21, theeCCE7 is configured with eREG9, eREG10, eREG11, and eREG12 of the DL PRBpair X illustrated in FIG. 21, the eCCE8 is configured with eREG13,eREG14, eREG15, and eREG16 of the DL PRB pair X illustrated in FIG. 21,the eCCE9 is configured with eREG1, eREG2, eREG3, and eREG4 of the DLPRB pair Y illustrated in FIG. 21, the eCCE10 is configured with eREG5,eREG6, eREG7, and eREG8 of the DL PRB pair Y illustrated in FIG. 21, theeCCE11 is configured with eREG9, eREG10, eREG11, and eREG12 of the DLPRB pair Y illustrated in FIG. 21, the eCCE12 is configured with eREG13,eREG14, eREG15, and eREG16 of the DL PRB pair Y illustrated in FIG. 21,the eCCE13 is configured with eREG1, eREG2, eREG3, and eREG4 of the DLPRB pair Z illustrated in FIG. 21, the eCCE14 is configured with eREG5,eREG6, eREG7, and eREG8 of the DL PRB pair Z illustrated in FIG. 21, theeCCE15 is configured with eREG9, eREG10, eREG11, and eREG12 of the DLPRB pair Z illustrated in FIG. 21, and the eCCE16 is configured witheREG13, eREG14, eREG15, and eREG16 of the DL PRB pair Z illustrated inFIG. 21. The following description will be given of the case in whichthe eCCE which is configured through the Localized mapping also isconfigured with a plurality of eREGs and the definition in common to theeREG used for configuring the eCCE which is configured through theLocalized mapping is used as the definition of the eREG (which physicalresources it is configured).

FIG. 22 is a diagram illustrating an example of a configuration of eREGof the embodiment of the present invention. Here, one DL PRB pair isillustrated. In FIG. 22, one square corresponds to one RE. In FIG. 22,the vertical axis represents a time domain and the horizontal axisrepresents a frequency domain. Here, the case is illustrated in whichUE-specific RSs corresponding to four antenna ports (antenna port 7,antenna port 8, antenna port 9, and antenna port 10) are configured. 168REs are configured in one DL PRB pair. 24 REs are configured for theUE-specific RSs corresponding to four antenna ports. eREGs areconfigured by using the remaining REs if the REs configured for theUE-specific RS is removed from the REs configured in the one DL PRBpair. Here, the eREGs are configured by using 144 REs in the one DL PRBpair. FIG. 22 illustrates the case in which 16 eREGs are configured inthe one DL PRB pair. Here, one eREG is configured with 9 REs obtained bydividing 144 REs by 16.

Nine REs configuring one eREG will be described in detail. The numberingstarts from a RE configured with the subcarrier of the lowest frequencyand an OFDM symbol of the earliest time, in the DL PRB pair. Next, thenumbering for the REs is performed in the frequency direction in order,if the numbering for the RE configured with the subcarrier of thehighest frequency in the OFDM symbol is performed, the numbering for theRE configured with the subcarrier of the lowest frequency and thesubsequent OFDM symbol is continuously performed. The same process asthe above process is performed on the REs configured with differentsubcarriers and the remaining REs configured with different OFDMsymbols, and the numbering is performed up to the RE configured with theOFDM symbol of the latest time and the subcarrier of the highestfrequency. Here, the numbering of the REs configuring eREG is performedwhile skipping the REs configured for the UE-specific RS. Further,numbering is performed, starting from the number ‘1’, in order of ‘2’,‘3’, ‘4’, ‘5’, ‘6’, ‘7’, ‘8’, ‘9’, ‘10’, ‘11’, ‘12’, ‘13’, ‘14’, ‘15’,and ‘16’. If numbering up to ‘16’ is performed, the numbering isrepeated starting from ‘1’ again. One eREG is configured with nine REsdenoted by the same number. For example, the eREG1 is configured withnine REs denoted by the number ‘1’, the eREG2 is configured with nineREs denoted by the number ‘2’, the eREG3 is configured with nine REsdenoted by the number ‘3’, the eREG4 is configured with nine REs denotedby the number ‘4’, the eREG5 is configured with nine REs denoted by thenumber ‘5’, the eREG6 is configured with nine REs denoted by the number‘6’, the eREG7 is configured with nine REs denoted by the number ‘7’,the eREG8 is configured with nine REs denoted by the number ‘8’, theeREG1 is configured with nine REs denoted by the number ‘9’, the eREG10is configured with nine REs denoted by the number ‘10’, the eREG11 isconfigured with nine REs denoted by the number ‘11’, the eREG12 isconfigured with nine REs denoted by the number ‘12’, the eREG13 isconfigured with nine REs denoted by the number ‘13’, the eREG14 isconfigured with nine REs denoted by the number ‘14’, the eREG15 isconfigured with nine REs denoted by the number ‘15’, and the eREG16 isconfigured with nine REs denoted by the number ‘16’.

Although the eREG is configured as FIG. 22, other signals, the signal ofthe second PDCCH is not mapped in REs in which for example, a CRS, afirst PDCCH, and a CSI-RS are mapped. Accordingly, a rate matchingprocess and a de-rate matching process in the processes of transmittingand receiving signals of the second PDCCH are performed in the basestation apparatus 3 and the mobile station apparatus 5, depending on thenumber of bits that can be transmitted and received in the resources ofeREG other than the REs in which the CRS, the first PDCCH, and theCSI-RS are mapped.

FIG. 23 is a diagram illustrating an example of a configuration of eREGof the embodiment of the present invention. FIG. 23 is different fromFIG. 22 in that UE-specific RSs corresponding to two antenna ports(antenna port 7 and antenna port 8) are configured. In FIG. 23, alleREGs are not configured with REs of the same number, but eREG1, eREG2,eREG3, eREG4, eREG5, eREG6, eREG7, eREG8, eREG9, eREG10, eREG11, andeREG12 are respectively configured with ten REs, and eREG13, eREG14,eREG15, and eREG16 are respectively configured with nine REs.

Different resource mapping methods (Localized mapping and Distributedmapping) may be applied to the second PDCCH region. For example, thesecond PDCCH configured with eCCE configured by the Localized mapping isreferred to as Localized ePDCCH. For example, the second PDCCHconfigured with eCCE configured by the Distributed mapping is referredto as Distributed ePDCCH.

For example, the Localized ePDCCH is configured with one eCCE (eCCEaggregation1), two eCCEs (eCCE aggregation2), or four eCCEs (eCCEaggregation4). The Localized ePDCCH having the eCCE aggregation numberof two or greater is configured with a plurality of eCCEs of which eCCEnumbers are consecutive. The Localized ePDCCH having the eCCEaggregation number of two or greater is configured with a plurality ofeCCEs configured with resources in the same DL PRB pair. For example, inFIG. 20, the Localized ePDCCH of the eCCE aggregation2 is configuredwith eCCE1 and eCCE2, eCCE3 and eCCE4, eCCE5 and eCCE6, eCCE7 and eCCE8,eCCE9 and eCCE10, eCCE11 and eCCE12, eCCE13 and eCCE14, or eCCE15 andeCCE16. For example, in FIG. 20, the Localized ePDCCH of the eCCEaggregation4 is configured with eCCE1, eCCE2, eCCE3 and eCCE4, or eCCE5,eCCE6, eCCE7, and eCCE8, or eCCE9, eCCE10, eCCE11 and eCCE12, or eCCE13,eCCE14, eCCE15, and eCCE16.

For example, the Distributed ePDCCH is configured with one eCCE (eCCEaggregation1), two eCCEs (eCCE aggregation2), four eCCEs (eCCEaggregation4), or eight eCCEs (eCCE aggregation8). The DistributedePDCCH having the eCCE aggregation number of two or greater isconfigured with a plurality of eCCEs of which eCCE numbers areconsecutive. For example, in FIG. 21, the Distributed ePDCCH of the eCCEaggregation2 is configured with eCCE1 and eCCE2, eCCE3 and eCCE4, eCCE5and eCCE6, eCCE7 and eCCE8, eCCE9 and eCCE10, eCCE11 and eCCE12, eCCE13and eCCE14, or eCCE15 and eCCE16. For example, in FIG. 21, theDistributed ePDCCH of the eCCE aggregation4 is configured with eCCE1,eCCE2, eCCE3 and eCCE4, or eCCE5, eCCE6, eCCE7, and eCCE8, or eCCE9,eCCE10, eCCE11 and eCCE12, or eCCE13, eCCE14, eCCE15, and eCCE16. Forexample, in FIG. 21, the Distributed ePDCCH of the eCCE aggregation8 isconfigured with eCCE1, eCCE2, eCCE3, eCCE4, eCCE5, eCCE6, eCCE7, andeCCE8, or eCCE9, eCCE10, eCCE11 and eCCE12, eCCE13, eCCE14, eCCE15, andeCCE16.

The second PDCCH region configured with common DL PRB pairs isconfigured in common for a plurality of mobile station apparatuses 5.Different second PDCCHs are transmitted and received for differentmobile station apparatuses 5, by using different eCCEs of the secondPDCCH region. When the second PDCCH region configured with common DL PRBpairs is configured in common, different resource mapping methods areapplied to different mobile station apparatuses 5, and the DistributedePDCCH and the Localized ePDCCH are transmitted and received todifferent mobile station apparatuses 5 in the second PDCCH region, theeREG in which the Distributed ePDCCH is transmitted and received and theeREG in which the Localized ePDCCH is transmitted and received aredifferent. For example, in a certain DL PRB pair, eREG1, eREG2, eREG3,eREG4, eREG5, eREG6, eREG7, and eREG8 may be used as resources of one ormore Distributed ePDCCHs, and eREG9, eREG10, eREG11, eREG12, eREG13,eREG14, eREG15, and eREG16 may be used as resources of one or moreLocalized ePDCCHs. The mobile station apparatus 5 assumes a resourcemapping method which is applied to a configured second PDCCH region andperforms a process of receiving, demodulating, and decoding the secondPDCCH. The base station apparatus 3 may determine one type of resourcemapping method which is applied to a certain configured second PDCCHregion, and perform a process of arranging and transmitting a pluralityof second PDCCHs, or may determine both two types of resource mappingmethods which are applied to a configured second PDCCH region, andperforms a process of arranging and transmitting a plurality of secondPDCCHs.

One or more second PDCCH regions are configured for the mobile stationapparatus 5 by the base station apparatus 3. For example, two secondPDCCH regions are configured which includes a second PDCCH region towhich the Distributed mapping and the random beamforming process areapplied and a second PDCCH region to which the Localized mapping and thebeamforming process suitable for the mobile station apparatus 5 areapplied. For example, two second PDCCH regions to which the Distributedmapping and the random beamforming process are applied are configured inthe mobile station apparatus 5.

The mobile station apparatus 5 is designated (set, configured) toperform a process of detecting (monitoring) the second PDCCH in thesecond PDCCH region that is configured by the base station apparatus 3.The designation of monitoring of the second PDCCH may be madeautomatically (implicitly) by the second PDCCH region being configuredfor the mobile station apparatus 5, or may be made explicitly by thesignaling different from the signaling indicating the configuration ofthe second PDCCH region. With respect to a plurality of mobile stationapparatuses 5, the same second PDCCH region may be designated by thebase station apparatus 3. The mobile station apparatus 5 does notperform the process of detecting the second PDCCH for all eCCEs of thesecond PDCCH region, but performs the process of detecting the secondPDCCH for the limited eCCEs. For example, an ePDCCH candidate fordetecting the second PDCCH is designated for each eCCE aggregationnumber.

First, the configuration of the ePDCCH candidate of the Localized ePDCCHin the second PDCCH region will be described by using FIG. 20. 16 ePDCCHcandidates (an ePDCCH candidate1, an ePDCCH candidate2, an ePDCCHcandidate3, an ePDCCH candidate4, an ePDCCH candidate5, an ePDCCHcandidate6, an ePDCCH candidate7, an ePDCCH candidate8, an ePDCCHcandidate9, an ePDCCH candidate10, an ePDCCH candidate11, an ePDCCHcandidate12, an ePDCCH candidate13, an ePDCCH candidate14, an ePDCCHcandidate15, and an ePDCCH candidate16) are configured as the ePDCCHcandidate of the Localized ePDCCH of the eCCE aggregation1, in thesecond PDCCH region. In the eCCE aggregation1, the ePDCCH candidate1 isconfigured with eCCE1, the ePDCCH candidate2 is configured with eCCE2,the ePDCCH candidate3 is configured with eCCE3, the ePDCCH candidate4 isconfigured with eCCE4, the ePDCCH candidate5 is configured with eCCE5,the ePDCCH candidate6 is configured with eCCE6, the ePDCCH candidate7 isconfigured with eCCE7, the ePDCCH candidate8 is configured with eCCE8,the ePDCCH candidate9 is configured with eCCE9, the ePDCCH candidate10is configured with eCCE10, the ePDCCH candidate11 is configured witheCCE11, the ePDCCH candidate12 is configured with eCCE12, the ePDCCHcandidate13 is configured with eCCE13, the ePDCCH candidate14 isconfigured with eCCE14, the ePDCCH candidate15 is configured witheCCE15, and the ePDCCH candidate16 is configured with eCCE16.

Eight ePDCCH candidates (an ePDCCH candidate1, an ePDCCH candidate2, anePDCCH candidate3, an ePDCCH candidate4, an ePDCCH candidate5, an ePDCCHcandidate6, an ePDCCH candidate7, and an ePDCCH candidate8) areconfigured as the ePDCCH candidate of the Localized ePDCCH of the eCCEaggregation2, in the second PDCCH region. In the eCCE aggregation2, theePDCCH candidate1 is configured with eCCE1 and eCCE2, the ePDCCHcandidate2 is configured with eCCE3 and eCCE4, the ePDCCH candidate3 isconfigured with eCCE5 and eCCE6, the ePDCCH candidate4 is configuredwith eCCE7 and eCCE8, the ePDCCH candidate5 is configured with eCCE9 andeCCE10, the ePDCCH candidate6 is configured with eCCE11 and eCCE12, theePDCCH candidate7 is configured with eCCE13 and eCCE14, and the ePDCCHcandidate8 is configured with eCCE15 and eCCE16.

Four ePDCCH candidates (an ePDCCH candidate1, an ePDCCH candidate2, anePDCCH candidate3, and an ePDCCH candidate4) are configured as theePDCCH candidate of the Localized ePDCCH of the eCCE aggregation4, inthe second PDCCH region. In the eCCE aggregation4, the ePDCCH candidate1is configured with eCCE1, eCCE2, eCCE3, and eCCE4, the ePDCCH candidate2is configured with eCCE5, eCCE6, eCCE7, and eCCE8, the ePDCCH candidate3is configured with eCCE9, eCCE10, eCCE11, and eCCE12, and the ePDCCHcandidate4 is configured with eCCE13, eCCE14, eCCE15, and eCCE16.

Next, the configuration of the ePDCCH candidate of the DistributedePDCCH in the second PDCCH region will be described by using FIG. 21. 16ePDCCH candidates (an ePDCCH candidate1, an ePDCCH candidate2, an ePDCCHcandidate3, an ePDCCH candidate4, an ePDCCH candidate5, an ePDCCHcandidate6, an ePDCCH candidate7, an ePDCCH candidate8, an ePDCCHcandidate9, an ePDCCH candidate10, an ePDCCH candidate11, an ePDCCHcandidate12, an ePDCCH candidate13, an ePDCCH candidate14, an ePDCCHcandidate15, and an ePDCCH candidate16) are configured as the ePDCCHcandidate of the Distributed ePDCCH of the eCCE aggregation1, in thesecond PDCCH region. In the eCCE aggregation1, the ePDCCH candidate1 isconfigured with eCCE1, the ePDCCH candidate2 is configured with eCCE2,the ePDCCH candidate3 is configured with eCCE3, the ePDCCH candidate4 isconfigured with eCCE4, the ePDCCH candidate5 is configured with eCCE5,the ePDCCH candidate6 is configured with eCCE6, the ePDCCH candidate7 isconfigured with eCCE7, the ePDCCH candidate8 is configured with eCCE8,the ePDCCH candidate9 is configured with eCCE9, the ePDCCH candidate10is configured with eCCE10, the ePDCCH candidate11 is configured witheCCE11, the ePDCCH candidate12 is configured with eCCE12, the ePDCCHcandidate13 is configured with eCCE13, the ePDCCH candidate14 isconfigured with eCCE14, the ePDCCH candidate15 is configured witheCCE15, and the ePDCCH candidate16 is configured with eCCE16.

Eight ePDCCH candidates (an ePDCCH candidate1, an ePDCCH candidate2, anePDCCH candidate3, an ePDCCH candidate4, an ePDCCH candidate5, an ePDCCHcandidate6, an ePDCCH candidate7, and an ePDCCH candidate8) areconfigured as the ePDCCH candidate of the Distributed ePDCCH of the eCCEaggregation2, in the second PDCCH region. In the eCCE aggregation2, theePDCCH candidate1 is configured with eCCE1 and eCCE2, the ePDCCHcandidate2 is configured with eCCE3 and eCCE4, the ePDCCH candidate3 isconfigured with eCCE5 and eCCE6, the ePDCCH candidate4 is configuredwith eCCE7 and eCCE8, the ePDCCH candidate5 is configured with eCCE9 andeCCE10, the ePDCCH candidate6 is configured with eCCE11 and eCCE12, theePDCCH candidate7 is configured with eCCE13 and eCCE14, and the ePDCCHcandidate8 is configured with eCCE15 and eCCE16.

Four ePDCCH candidates (an ePDCCH candidate1, an ePDCCH candidate2, anePDCCH candidate3, and ePDCCH candidate4) are configured as the ePDCCHcandidate of the Distributed ePDCCH of the eCCE aggregation4, in thesecond PDCCH region. In the eCCE aggregation4, the ePDCCH candidate1 isconfigured with eCCE1, eCCE2, eCCE3, and eCCE4, the ePDCCH candidate2 isconfigured with eCCE5, eCCE6, eCCE7, and eCCE8, the ePDCCH candidate3 isconfigured with eCCE9, eCCE10, eCCE11, and eCCE12, and the ePDCCHcandidate4 is configured with eCCE13, eCCE14, eCCE15, and eCCE16.

Two ePDCCH candidates (an ePDCCH candidate1 and an ePDCCH candidate2)are configured as the ePDCCH candidate of the Distributed ePDCCH of theeCCE aggregation8, in the second PDCCH region. In the eCCE aggregation8,the ePDCCH candidate1 is configured with eCCE1, eCCE2, eCCE3, eCCE4,eCCE5, eCCE6, eCCE7, and eCCE8, and the ePDCCH candidate2 is configuredwith eCCE9, eCCE10, eCCE11, eCCE12, eCCE13, eCCE14, eCCE15, and eCCE16.

For example, whether to perform a process of detecting a second PDCCHfor any ePDCCH candidate for each second PDCCH region is indicated by abitmap configured with one bit for each ePDCCH candidate (is referred toas ePDCCH candidate bitmap). The mobile station apparatus 5 performs theprocess of detecting a second PDCCH for the ePDCCH candidate denoted bybit ‘1’, and the mobile station apparatus 5 does not perform the processof detecting a second PDCCH for the ePDCCH candidate denoted by bit ‘0’.The ePDCCH candidate bitmap for each eCCE aggregation number is notifiedfrom the base station apparatus 3 to the mobile station apparatus 5.

Before communication using the second PDCCH is started, informationindicating the configuration (designation and configuring) of the secondPDCCH region is exchanged between the base station apparatus 3 and themobile station apparatus 5. For example, the information is exchangedusing a Radio Resource Control (RRC) signaling. Specifically, the mobilestation apparatus 5 receives information indicating the position(allocation) of the DL PRB pairs of the second PDCCH region from thebase station apparatus 3. Further, information indicating the type(Localized mapping or Distributed mapping) of the resource mapping ofeCCE for each second PDCCH region is notified from the base stationapparatus 3 to the mobile station apparatus 5. In addition, aconfiguration is possible in which other types of information other thaninformation explicitly indicating the type of the resource mappingapplied to the second PDCCH region is notified from the base stationapparatus 3 to the mobile station apparatus 5, and the mobile stationapparatus 5 implicitly recognizes the type of resource mapping of theeCCE of the second PDCCH based on the information. For example,information indicating a transmission method of the second PDCCH in eachsecond PDCCH region is notified from the base station apparatus 3 to themobile station apparatus 5. When the information indicates atransmission method in which a beamforming process suitable for themobile station apparatus 5 is applied, the mobile station apparatus 5recognizes that the resource mapping of the eCCE of the second PDCCHregion is Localized mapping, and when the information indicates atransmission method in which a random beamforming process is applied,the mobile station apparatus 5 recognizes that the resource mapping ofthe eCCE of the second PDCCH region is Distributed mapping. Further,only when resource mapping of the eCCE of a certain second PDCCH isconfigured in advance as a default and the resource mapping of the eCCEdifferent from the configuring is used, information indicating the factmay be notified to the mobile station apparatus 5 from the base stationapparatus 3. Further, it may be determined in advance that one of thetypes of resource mapping of the eCCE, for example, Distributed mappingis to be applied, in some second PDCCH regions.

The mobile station apparatus 5 performs demodulation of the signals ofthe second PDCCH by using a UE-specific RS received within the secondPDCCH region which is configured by the base station apparatus 3, andperforms a process of detecting the second PDCCH addressed to the mobilestation apparatus 5. The mobile station apparatus 5 performsdemodulation of signals of the second PDCCH, by using the UE-specific RSin the DL PRB pair to which the resource for performing demodulationbelongs. The association between the eREG and a certain antenna port isconfigured in advance, and the mobile station apparatus 5 performsdemodulation of signals of the second PDCCH, by using the UE-specific RSof the antenna port which is determined based on the eREG configuringthe second PDCCH. Further, in the second PDCCH region to which theLocalized mapping is applied and the second PDCCH region to which theDistributed mapping is applied, another association may be used withrespect to the association between the eREG in the DL PRB pair and theantenna port.

In the following description, control signals mapped to the second PDCCHwill be described. The control signal mapped to the second PDCCH isprocessed for each piece of control information (DCI) for one mobilestation apparatus 5, and is subjected to a scramble process, amodulation process, a layer mapping process, a pre-coding process andthe like. Here, the layer mapping process means some MIMO signalprocesses performed when transmission through a plurality of antennas isapplied to the second PDCCH. Further, a common pre-coding process can beperformed on the control signal mapped to the second PDCCH and theUE-specific RS. At this time, it is preferable that the pre-codingprocess be performed by a pre-coding weighting suitable for the unit ofthe mobile station apparatus 5.

Further, the UE-specific RS is multiplexed by the base station apparatus3 in the DL PRB pair in which the second PDCCH is allocated. The mobilestation apparatus 5 performs the demodulation process on the signals ofthe second PDCCH by the UE-specific RS. As the UE-specific RS used indemodulation of the second PDCCH, the UE-specific RS of the antenna portcorresponding to the eREG or the eCCE configuring the second PDCCH isused. The antenna port corresponding to the eREG or the eCCE of thesecond PDCCH is configured in advance.

For example, in FIG. 20, the second PDCCH region to which the Localizedmapping is applied is configured in advance such that the eCCE1, theeCCE5, the eCCE9, and the eCCE13 correspond to the antenna port 7, theeCCE2, the eCCE6, the eCCE10, and the eCCE14 correspond to the antennaport 8, the eCCE3, the eCCE7, the eCCE11, and the eCCE15 correspond tothe antenna port 9, the eCCE4, the eCCE8, the eCCE12, and the eCCE16correspond to the antenna port 10, and such a configuring is used in thecase, for example, in which the UE-specific RS of four antenna ports areconfigured in the second PDCCH region as illustrated in FIG. 22. Forexample, in FIG. 20, the second PDCCH region to which the Localizedmapping is applied is configured in advance such that the eCCE1, theeCCE5, the eCCE9, and the eCCE13 correspond to the antenna port 7, theeCCE2, the eCCE6, the eCCE10, and the eCCE14 correspond to the antennaport 7, the eCCE3, the eCCE7, the eCCE11, and the eCCE15 correspond tothe antenna port 8, the eCCE4, the eCCE8, the eCCE12, and the eCCE16correspond to the antenna port 8, and such a configuring is used in thecase, for example, in which the UE-specific RS of two antenna ports areconfigured in the second PDCCH region as illustrated in FIG. 23.

For example, in FIG. 21, the second PDCCH region to which theDistributed mapping is applied is configured in advance such that theeCCE1, the eCCE2, the eCCE3, and the eCCE4 correspond to the antennaport 7, the eCCE5, the eCCE6, the eCCE7, and the eCCE8 correspond to theantenna port 8, the eCCE9, the eCCE10, the eCCE11, and the eCCE12correspond to the antenna port 9, the eCCE13, the eCCE14, the eCCE15,and the eCCE16 correspond to the antenna port 10, and such a configuringis used in the case, for example, in which the UE-specific RS of fourantenna ports are configured in the second PDCCH region as illustratedin FIG. 22. For example, in FIG. 21, the second PDCCH region to whichthe Distributed mapping is applied is configured in advance such thatthe eCCE1, the eCCE2, the eCCE3, and the eCCE4 correspond to the antennaport 7, the eCCE5, the eCCE6, the eCCE7, and the eCCE8 correspond to theantenna port 7, the eCCE9, the eCCE10, the eCCE11, and the eCCE12correspond to the antenna port 8, the eCCE13, the eCCE14, the eCCE15,and the eCCE16 correspond to the antenna port 8, and such a configuringis used in the case, for example, in which the UE-specific RS of twoantenna ports are configured in the second PDCCH region as illustratedin FIG. 23.

When the eCCEs of the Distributed mapping are configured with the eREGillustrated in FIG. 21, and with respect to the eCCEs of the Localizedmapping illustrated in FIG. 20, the eCCE1 of the Localized mapping isconfigured with eREG1, eREG2, eREG3 and eREG4 of the DL PRB pair W, theeCCE2 of the Localized mapping is configured with eREG5, eREG6, eREG7and eREG8 of the DL PRB pair W, the eCCE3 of the Localized mapping isconfigured with eREG9, eREG10, eREG11 and eREG12 of the DL PRB pair W,the eCCE4 of the Localized mapping is configured with eREG13, eREG14,eREG15 and eREG16 of the DL PRB pair W, the eCCE5 of the Localizedmapping is configured with eREG1, eREG2, eREG3 and eREG4 of the DL PRBpair X, the eCCE6 of the Localized mapping is configured with eREG5,eREG6, eREG7 and eREG8 of the DL PRB pair X, the eCCE7 of the Localizedmapping is configured with eREG9, eREG10, eREG11 and eREG12 of the DLPRB pair X, the eCCE8 of the Localized mapping is configured witheREG13, eREG14, eREG15 and eREG16 of the DL PRB pair X, the eCCE9 of theLocalized mapping is configured with eREG1, eREG2, eREG3 and eREG4 ofthe DL PRB pair Y, the eCCE10 of the Localized mapping is configuredwith eREG5, eREG6, eREG7 and eREG8 of the DL PRB pair Y, the eCCE11 ofthe Localized mapping is configured with eREG9, eREG10, eREG11 andeREG12 of the DL PRB pair Y, the eCCE12 of the Localized mapping isconfigured with eREG13, eREG14, eREG15 and eREG16 of the DL PRB pair Y,the eCCE13 of the Localized mapping is configured with eREG1, eREG2,eREG3 and eREG4 of the DL PRB pair Z, the eCCE14 of the Localizedmapping is configured with eREG5, eREG6, eREG7 and eREG8 of the DL PRBpair Z, the eCCE15 of the Localized mapping is configured with eREG9,eREG10, eREG11 and eREG12 of the DL PRB pair Z, and the eCCE16 of theLocalized mapping is configured with eREG13, eREG14, eREG15 and eREG16of the DL PRB pair Z, each eREG and each antenna port correspond witheach other, and the mobile station apparatus 5 may determine the antennaport of the UE-specific RS used in demodulation from the eREGconfiguring the second PDCCH. For example, the second PDCCH region towhich the Localized mapping is applied and the second PDCCH region towhich the Distributed mapping is applied are configured in advance suchthat the eREG1, the eREG2, the eREG3, and the eREG4 correspond to theantenna port 7, the eREG5, the eREG6, the eREG7, and the eREG8correspond to the antenna port 8, the eREG9, the eREG10, the eREG11, andthe eREG12 correspond to the antenna port 9, the eREG13, the eREG14, theeREG15, and the eREG16 correspond to the antenna port 10, and such aconfiguring is used in the case, for example, in which the UE-specificRS of four antenna ports are configured in the second PDCCH region asillustrated in FIG. 22. For example, the second PDCCH region to whichthe Localized mapping is applied and the second PDCCH region to whichthe Distributed mapping is applied are configured in advance such thatthe eREG1, the eREG2, the eREG3, the eREG4, the eREG5, the eREG6, theeREG7, and the eREG8 correspond to the antenna port 7, and the eREG9,the eREG10, the eREG11, the eREG12, the eREG13, the eREG14, the eREG15,and the eREG16 correspond to the antenna port 8, and such a configuringis used in the case, for example, in which the UE-specific RS of twoantenna ports are configured in the second PDCCH region as illustratedin FIG. 23.

In addition, when the eCCE aggregation number is two or greater, controlmay be performed such that only one antenna port is used for the secondPDCCH. For example, when the Localized ePDCCH of the eCCE aggregation2is configured with the eCCE1 and the eCCE2 which are illustrated in FIG.20, and a configuring is made in advance such that the eCCE1 correspondsto the antenna port 7, and the eCCE2 corresponds to the antenna port 8,the base station apparatus 3 may transmit the signals of the LocalizedePDCCH and the UE-specific RS to the mobile station apparatus 5, byusing only the antenna port 7 or the antenna port 8, and the mobilestation apparatus 5 may demodulate the signals of the Localized ePDCCHby using the UE-specific RS of the antenna port 7 or the antenna port 8.Further, in the eCCE aggregation4, control may be performed such thatonly two antenna ports are used for the second PDCCH. For example, whenthe Localized ePDCCH of the eCCE aggregation4 is configured with theeCCE1, the eCCE2, the eCCE3, and the eCCE4 which are illustrated in FIG.20, and a configuring is made in advance such that the eCCE1 correspondsto the antenna port 7, the eCCE2 corresponds to the antenna port 8, theeCCE3 corresponds to the antenna port 9, and the eCCE4 corresponds tothe antenna port 10, the base station apparatus 3 may transmit thesignals of the eCCE1 and the eCCE2 of the Localized ePDCCH and theUE-specific RS to the mobile station apparatus 5, by using only theantenna port 7 or the antenna port 8, and transmit the signals of theeCCE3 and the eCCE4 of the Localized ePDCCH and the UE-specific RS tothe mobile station apparatus 5, by using only the antenna port 9 or theantenna port 10, and the mobile station apparatus 5 may demodulate thesignals of the eCCE1 and the eCCE2 of the Localized ePDCCH by using theUE-specific RS of the antenna port 7 or the antenna port 8, anddemodulate the signals of the eCCE3 and the eCCE4 of the LocalizedePDCCH by using the UE-specific RS of the antenna port 9 or the antennaport 10. In this case, the base station apparatus 3 forms the antennaport used for transmission of signals of the eCCE1 and the eCCE2, andthe antenna port used for transmission of signals of the eCCE3 and theeCCE4, by a common pre-coding process such that it is possible toimprove the characteristics of the channel estimation in the mobilestation apparatus 5. With respect to a plurality of eCCEs configuringthe Localized ePDCCH, a plurality of eCCEs corresponding to a pluralityof antenna ports in which the UE-specific RSs are mapped in the samedownlink resource element may be transmitted by using any antenna port,and a plurality of eCCEs corresponding to a plurality of antenna portsin which the UE-specific RSs are mapped in different downlink resourceelements may be transmitted by using respectively different antennaports.

FIG. 24 is a diagram illustrating an example of monitoring of the secondPDCCH of the mobile station apparatus 5 according to the embodiment ofthe present invention. FIG. 24 describes the case in which two secondPDCCH regions (second PDCCH region 1 and second PDCCH region 2) areconfigured for the mobile station apparatus 5. In the mobile stationapparatus 5, a search space is configured in each second PDCCH region.The search space means a logical region in which the mobile stationapparatus 5 performs decoding detection of the second PDCCH in thesecond PDCCH region. The search space is configured with a plurality ofsecond PDCCH candidates. The second PDCCH candidates are to be subjectedto the decoding detection of the second PDCCH by the mobile stationapparatus 5. For each eCCE aggregation number, different second PDCCHcandidates are configured with different eCCEs (including one eCCE, anda plurality of eCCEs).

In the mobile station apparatus 5 in which a plurality of second PDCCHregions are configured, a plurality of search spaces (first searchspace, second search space) are configured. For example, the Distributedmapping is applied to some second PDCCH region of a plurality of secondPDCCH regions configured in the mobile station apparatus 5, and theLocalized mapping is applied to some different second PDCCH region.

The number of second PDCCH candidates of the first search space may bedifferent from the number of candidates of the second PDCCH of thesecond search space. Further, in a certain eCCE aggregation number, thenumber of second PDCCH candidates of the first search space and thenumber of second PDCCH candidates of the second search space may be thesame; and in different eCCE aggregation number, the number of secondPDCCH candidates of the first search space and the number of secondPDCCH candidates of the second search space may be different. Further,in a certain eCCE aggregation number, the number of second PDCCHcandidates of the first search space may be more than the number ofsecond PDCCH candidates of the second search space; and in differenteCCE aggregation number, the number of second PDCCH candidates of thefirst search space may be less than the number of second PDCCHcandidates of the second search space. Further, the second PDCCHcandidate of a certain eCCE aggregation number may be configured in thesearch space of one second PDCCH region, and may not be configured inthe search space of the other second PDCCH region. Further, the numberof second PDCCH candidates of the search space in one second PDCCHregion may be changed, depending on the number of second PDCCH regionsconfigured in the mobile station apparatus 5. For example, the number ofsecond PDCCH candidates of the search space in one second PDCCH regionmay be reduced, with an increase in the number of the second PDCCHregions configured in the mobile station apparatus 5.

In the communication system 1, as illustrated in FIG. 15, a plurality ofPUCCH resources for transmission and reception of ACK/NACK (hereinafter,referred to as ACK/NACK PUCCH) are prepared. In the prepared resourcesof ACK/NACK PUCCH, the ACK/NACK PUCCH resource for which the UL PRBpairs configuring the ACK/NACK PUCCH resource are located near to theedge in the uplink system band is used for transmission and reception ofACK/NACK (hereinafter, referred to as SPS ACK/NACK) for PDSCH of ascheduling (Persistent scheduling, Semi-Persistent scheduling: SPS) inwhich PDCCH is not basically used for resource allocation of PDSCH.During the SPS, the base station apparatus 3 notifies in advance themobile station apparatus 5 of a DL PRB pair in which the PDSCH for amobile station apparatus 5 may be allocated and transmitted by the basestation apparatus 3, and the mobile station apparatus 5 performsdemodulation and decoding of the PDSCH from the notified DL PRB pair,checks CRC, confirms whether or not the PDSCH addressed to the mobilestation apparatus is transmitted, and when it is determined that thereis the PDSCH addressed to the mobile station apparatus 5, the mobilestation apparatus 5 uses the detected data. Since during the SPS, one ormore DL PRB pairs as the resource of the frequency domain are notifiedto the mobile station apparatus 5 in advance and a downlink subframe inwhich PDSCH may be allocated is indicated, the period of the downlinksubframe as the resource of the time domain is notified to the mobilestation apparatus 5 in advance. In this manner, during the SPS, theresource to which the PDSCH is actually allocated is not indicated bythe first PDCCH and a first PDCCH is not used. Since the first PDCCH isnot used, the ACK/NACK PUCCH resources are implicitly indicateddepending on the CCE index, and an allocation method cannot be used, thebase station apparatus 3 explicitly notifies the mobile stationapparatus 5 of the resource of the PUCCH used for the PDSCH of SPS byusing signaling.

It is preferable from the viewpoint of effective utilization of theuplink resource that the ACK/NACK PUCCH resource which is continuous tothe ACK/NACK PUCCH resource which is allocated for the SPS ACK/NACK beused, with respect to the ACK/NACK PUCCH resource for the PDSCH ofscheduling (dynamic scheduling) in which PDCCH is basically used for theresource allocation of the PDSCH. Since the number of mobile stationapparatuses 5 using the SPS is not constant and varies, it is preferablethat the ACK/NACK PUCCH resources of all uplink system bands in whichthe ACK/NACK PUCCH resource for the PDSCH of the dynamic scheduling isstarted (started to use) can be controlled by the base station apparatus3. Further, in the dynamic scheduling, the actual allocation of thePDSCH is indicated by the first PDCCH, and the ACK/NACK PUCCH resourceis implicitly allocated to the mobile station apparatus 5, according tothe CCE index of one or more CCEs used in the first PDCCH. Hereinafter,the ACK/NACK for PDSCH of the dynamic scheduling is referred to asDynamic ACK/NACK.

In order to realize the above demands, information indicating theACK/NACK PUCCH resource in which the association with the CCE index isstarted is notified to the mobile station apparatus 5 from the basestation apparatus 3. In the embodiment of the present invention, in thedynamic scheduling in which the second PDCCH is basically used for theresource allocation of PDSCH, the ACK/NACK PUCCH resources are allocatedimplicitly to the mobile station apparatus 5 according to the eCCEindexes of one or more eCCEs used in the second PDCCH. In the embodimentof the present invention, the base station apparatus 3 configures theACK/NACK PUCCH resource in which the association with the eCCE index ofthe second PDCCH region is started, with respect to each of a pluralityof second PDCCH regions configured in the mobile station apparatus 5,and notifies the mobile station apparatus 5 of the information by usingRRC signaling, the mobile station apparatus 5 recognizes the ACK/NACKPUCCH resource in which the association with the eCCE indexes of therespective configured second PDCCH regions is started, based on thereceived information, and the base station apparatus 3 and the mobilestation apparatus 5 transmits and receives the ACK/NACK PUCCH. As theinformation indicating the ACK/NACK PUCCH resource in which theassociation with the eCCE index is started, an offset indicating adifference between the PUCCH resource index of the ACK/NACK PUCCHresource in which the association with the eCCE index is started and thePUCCH resource index of the first number of the ACK/NACK PUCCH resourceof the uplink system band (hereinafter, referred to as PUCCH resourceoffset) is used.

A method of implicitly allocating the ACK/NACK PUCCH resource from eCCEsconfiguring the second PDCCH will be described. The eCCE of the secondPDCCH region and the ACK/NACK PUCCH resource are associated based on apredetermined rule. The identification number of eCCE (eCCE index) andthe identification number of the ACK/NACK PUCCH resource (PUCCH resourceindex) are associated in advance, and the PUCCH resource index of thevalue to which the PUCCH resource offset is added is associated with theeCCE index. For example, the mobile station apparatus 5 transmitsACK/NACK for data of PDSCH of which the allocation of resource isindicated by the second PDCCH (signal obtained by modulating theinformation of ACK/NACK), by using the ACK/NACK PUCCH resourcecorresponding to the eCCE having the smallest number, among eCCEs usedin the second PDCCH from which DCI addressed to the mobile stationapparatus 5 is detected. The base station apparatus 3 recognizes theallocation between the eCCE and the ACK/NACK PUCCH resource in the samemanner as the mobile station apparatus 5, and allocates the eCCEs usedin the second PDCCH in view of the ACK/NACK PUCCH resource allocated inthe mobile station apparatus 5. In other words, the mobile stationapparatus 5 recognizes the ACK/NACK PUCCH resource allocated to themobile station apparatus 5, based on the eCCEs used in the second PDCCHfrom which DCI addressed to the mobile station apparatus 5 is detected.

FIG. 25 is a diagram conceptually describing association between theACK/NACK PUCCH resource and eCCE of the second PDCCH region of theembodiment of the present invention. Here, the case will be described inwhich the base station apparatus 3 configures three second PDCCH regions(a second PDCCH region 1, a second PDCCH region 2, and a second PDCCHregion 3) in the communication system 1. The resources having the PUCCHresource indexes of the first half among the ACK/NACK PUCCH resources ofthe uplink system band are used for SPS ACK/NACK. The resources havingthe numbers subsequent to the PUCCH resources for the SPS ACK/NACK areused for the Dynamic ACK/NACK. The association with the eCCE of thesecond PDCCH region 1 is started from the resource having the numbernext to the PUCCH resources for the SPS ACK/NACK. The PUCCH resourceindex in which the association with the eCCE of the second PDCCH region1 is started is a value obtained by adding the Offset X1 to the PUCCHresource index of the first number of the ACK/NACK PUCCH resource of theuplink system band. Next, the association with the eCCE of the secondPDCCH region 2 is started from the resource of the number next to theACK/NACK PUCCH resource corresponding to the eCCE of which the eCCEindex of the second PDCCH region 1 is the last number. The PUCCHresource index in which the association with the eCCE of the secondPDCCH region 2 is started is a value obtained by adding the Offset X2 tothe PUCCH resource index of the first number of the ACK/NACK PUCCHresource of the uplink system band. Next, the association with the eCCEof the second PDCCH region 3 is started from the resource of the numbernext to the ACK/NACK PUCCH resource corresponding to the eCCE of whichthe eCCE index of the second PDCCH region 2 is the last number. ThePUCCH resource index in which the association with the eCCE of thesecond PDCCH region 3 is started is a value obtained by adding theOffset X3 to the PUCCH resource index of the first number of theACK/NACK PUCCH resource of the uplink system band. In addition, withrespect to the Offset X1, the Offset X2, and the Offset X3, there is arelationship that Offset X1<Offset X2<Offset X3.

The base station apparatus 3 configures the PUCCH resource offset foreach second PDCCH region configured for the mobile station apparatus 5,and notifies the mobile station apparatus 5 of the PUCCH resource offsetwhich is configured for each second PDCCH region. The mobile stationapparatus 5 is notified of the PUCCH resource offset for each secondPDCCH region configured in the mobile station apparatus 5 from the basestation apparatus 3, and recognizes the ACK/NACK PUCCH resourcecorresponding to the eCCE of each second PDCCH region. For example, themobile station apparatus 5 for which the second PDCCH region 1 and thesecond PDCCH region 2 are configured is notified of Offset X1 as thePUCCH resource offset used in the second PDCCH region 1 and is notifiedof Offset X2 as the PUCCH resource offset used in the second PDCCHregion 2. For example, the mobile station apparatus 5 for which thesecond PDCCH region 1 and the second PDCCH region 3 are configured isnotified of Offset X1 as the PUCCH resource offset used in the secondPDCCH region 1 and is notified of Offset X3 as the PUCCH resource offsetused in the second PDCCH region 3. In addition, the offset is notifiedfrom the base station apparatus 3 to the mobile station apparatus 5 byusing RRC signaling.

As described above, the PUCCH resource offset is configured for eachsecond PDCCH region and used, such that it is possible to use differentACK/NACK PUCCH resources for the eCCEs of different second PDCCHregions, and prevent the different mobile station apparatuses for whichthe PDSCHs are allocated to the second PDCCH in different second PDCCHregions from using the same ACK/NACK PUCCH resource, in other words, itis possible to avoid the collision of the uplink signals between themobile station apparatuses 5. Further, the base station apparatus 3 canappropriately control the ACK/NACK PUCCH resources for dynamic ACK/NACKwhich are prepared in the uplink system band according to the number ofsecond PDCCH regions configured for a plurality of mobile stationapparatuses 5, and avoid an increase in the overhead on the ACK/NACKPUCCH of the uplink system band. If the eCCEs of the second PDCCH regionconfigured with DL PRB pairs are determined in advance according to theDL PRB pairs which are physically configured, and different ACK/NACKPUCCH resources are prepared for the eCCEs of the second PDCCH regionconfigured with DL PRB pairs which may all be DL PRB pairs, thecollision of the ACK/NACK signals between the mobile station apparatuses5 is avoided, but the overhead on the ACK/NACK PUCCH of the uplinksystem band is increased significantly. According to the embodiment ofthe present invention, it is possible to avoid collision of ACK/NACKsignals between the mobile station apparatuses 5, while avoiding anincrease in uplink overhead.

<Overall Configuration of Base Station Apparatus 3>

Hereinafter, the configuration of the base station apparatus 3 accordingto the present embodiment will be described with reference to FIGS. 1 to3. FIG. 1 is a schematic block diagram showing a configuration of thebase station apparatus 3 according to an embodiment of the presentinvention. As illustrated in FIG. 1, the base station apparatus 3 isconfigured to include a reception processing unit (a second receptionprocessing unit) 101, a radio resource control unit (a second radioresource control unit) 103, a control unit 105, and a transmissionprocessing unit (a second transmission processing unit) 107.

The reception processing unit 101 demodulates and decodes receptionsignals of the PUCCH and the PUSCH which are received from the mobilestation apparatus 5 by the receive antenna 109 according to aninstruction of the control unit 105 using the UL RS, and extractscontrol information and information data. The reception processing unit101 performs a process to extract UCI on the uplink subframe and the ULPRB in which the base station apparatus 3 allocates the PUCCH resourceto the mobile station apparatus 5. The control unit 105 instructs whichprocess the reception processing unit 101 is to perform for which uplinksubframe and which UL PRB. For example, the control unit 105 instructsthe reception processing unit 101 to perform a detection process ofperforming a multiplication and a combining of code sequences in thetime domain and a multiplication and a combining of code sequences inthe frequency domain for the signals in the PUCCH for ACK/NACK (PUCCHformat 1a and PUCCH format 1b). The control unit 105 instructs thereception processing unit 101 of code sequences in the frequency domainand/or the code sequences in the time domain which are used in theprocess of detecting UCI from the PUCCH. The reception processing unit101 outputs the extracted UCI to the control unit 105 and outputsinformation data to a higher layer. The details of the receptionprocessing unit 101 will be described later.

Further, the reception processing unit 101 detects (receives) a preamblesequence from the reception signal of the PRACH which is received by thereceive antenna 109 from the mobile station apparatus 5, according to aninstruction of the control unit 105. Further, the reception processingunit 101 performs estimation of an arrival timing (reception timing)together with the detection of the preamble sequence. The receptionprocessing unit 101 performs a process to detect the preamble sequencefor the uplink subframe and the UL PRB pair in which the base stationapparatus 3 allocates the PRACH resource. The reception processing unit101 outputs information regarding the estimated arrival timing to thecontrol unit 105.

Further, the reception processing unit 101 measures channel quality ofone or more UL PRB (UL PRB pair), using a SRS received from the mobilestation apparatus 5. Further, the reception processing unit 101 detects(calculates and measures) synchronization deviation of the uplink, usingthe SRS received from the mobile station apparatus 5. The control unit105 instructs which process the reception processing unit 101 is toperform for which uplink subframe and which UL PRB (UL PRB pair). Thereception processing unit 101 outputs information regarding the measuredchannel quality and detected synchronization deviation of the uplink tothe control unit 105. The details of the reception processing unit 101will be described later.

The radio resource control unit 103 configures allocation of theresource for the PDCCH (the first PDCCH and the second PDCCH),allocation of the resource for the PUCCH, allocation of the DL PRB pairfor the PDSCH, allocation of the UL PRB pair for the PUSCH, allocationof the resource for the PRACH, allocation of the resource for the SRS,modulation schemes⋅coding rates⋅transmission power control values⋅phaserotation amounts (weighting value) used in the pre-coding process ofvarious channels, a phase rotation amount (weighting value) used in thepre-coding process of the UE-specific RS, and the like. Further, theradio resource control unit 103 configures the code sequence of thefrequency domain, the code sequence of the time domain for the PUCCH,and the like. Further, the radio resource control unit 103 configures aplurality of second PDCCH regions, and configures the DL PRB pair usedin each second PDCCH region. Further, the radio resource control unit103 configures a resource mapping method of eCCE of each second PDCCHregion for each mobile station apparatus 5. Further, the radio resourcecontrol unit 103 configures a PUCCH resource offset for each secondPDCCH region. Some pieces of information which are configured by theradio resource control unit 103 are notified to the mobile stationapparatus 5 through the transmission processing unit 107, and forexample, information indicating DL PRB pairs in the second PDCCH region,information indicating a resource mapping method of eCCE of the secondPDCCH region, and information indicating a PUCCH resource offset foreach second PDCCH region are notified to the mobile station apparatus 5.

Further, the radio resource control unit 103 configures allocation ofthe PDSCH radio resource, based on the UCI which is obtained using thePUCCH in the reception processing unit 101 and is input through thecontrol unit 105. For example, when ACK/NACK obtained using the PUCCH isinput, the radio resource control unit 103 performs allocation of thePDSCH resource shown by the NACK in the ACK/NACK with respect to themobile station apparatus 5.

The radio resource control unit 103 outputs various control signals tothe control unit 105. For example, the control signals include a controlsignal indicating a method of resource mapping of the second PDCCHregion, a control signal indicating a ACK/NACK PUCCH resource, a controlsignal indicating allocation of the second PDCCH resource, a controlsignal indicating a phase rotation amount used in the pre-codingprocess, and the like.

The control unit 105 performs control such as allocation of the DL PRBpair for the PDSCH, allocation of the resource for the PDCCH,configuring of a modulation scheme for the PDSCH, configuring of thecoding rates for the PDSCH and the PDCCH (eCCE aggregation number of thesecond PDCCH), configuring of the UE-specific RS of the second PDCCHregion, configuring of the antenna port for transmitting the eCCEsignal, and configuring of the pre-coding process for the PDSCH, thePDCCH and the UE-specific RS for the transmission processing unit 107,based on the control signal which is input from the radio resourcecontrol unit 103. Further, the control unit 105 generates DCI to betransmitted using the PDCCH based on the control signal which is inputfrom the radio resource control unit 103 and outputs the DCI to thetransmission processing unit 107. The DCI transmitted using the PDCCH isa downlink assignment, an uplink grant, and the like. Further, thecontrol unit 105 performs control such that information indicating thesecond PDCCH region, information indicating a resource mapping method ofthe eCCE of the second PDCCH region, information indicating a PUCCHresource offset for each second PDCCH region, and the like aretransmitted to the mobile station apparatus 5 through the transmissionprocessing unit 107 by using the PDSCH.

The control unit 105 performs control such as allocation of the UL PRBpair for the PUSCH, allocation of the resource for the PUCCH,configuring of modulation schemes of the PUSCH and the PUCCH,configuring of a coding rate of the PUSCH, a detection process for thePUCCH, configuring of a code sequence for the PUCCH, allocation of theresource for the PRACH, and allocation of the resource for the SRS, forthe reception processing unit 101, based on the control signal which isinput from the radio resource control unit 103. For example, the controlunit 105 performs configuring of the ACK/NACK PUCCH resource to besubjected to the reception process for the reception processing unit 101in order to achieve the ACK/NACK for the PDSCH for which resourceallocation is indicated by the second PDCCH. Further, the control unit105 inputs the UCI transmitted using the PUCCH by the mobile stationapparatus 5 through the reception processing unit 101 and outputs theinput UCI to the radio resource control unit 103.

Further, if information indicating an arrival timing of the detectedpreamble sequence and information indicating synchronization deviationof the uplink which is detected from the received SRS is input by thereception processing unit 101, the control unit 105 calculates anadjustment value of a transmission timing of the uplink (TA value, TA:Timing Advance, Timing Adjustment, Timing Alignment). Informationindicating the calculated adjustment value of the transmission timing ofthe uplink (TA command) is notified to the mobile station apparatus 5through the transmission processing unit 107.

The transmission processing unit 107 generates a signal transmittedusing the PDCCH and PDSCH based on the control signal which is inputfrom the control unit 105, and transmits the generated signals throughthe transmit antenna 111. The transmission processing unit 107 transmitsinformation indicating the second PDCCH region, information indicating aresource mapping method of eCCE of each second PDCCH region, informationindicating a PUCCH resource offset for each second PDCCH region whichare input from the radio resource control unit 103, information datawhich is input from the higher layer, and the like, by using the PDSCH,to the mobile station apparatus 5, and transmits DCI which is input fromthe control unit 105, to the mobile station apparatus 5, by using thePDCCH (the first PDCCH and the second PDCCH). Further, the transmissionprocessing unit 107 transmits the CRS, the UE-specific RS, and theCSI-RS. In addition, for simplicity of explanation, hereinafter, it isassumed that information data includes information regarding varioustypes of control. The details of the transmission processing unit 107will be described later.

<Configuration of Transmission Processing Unit 107 of Base StationApparatus 3>

Hereinafter, the details of the transmission processing unit 107 of thebase station apparatus 3 will be described. FIG. 2 is a schematic blockdiagram showing a configuration of a transmission processing unit 107 ofthe base station apparatus 3 according to the embodiment of the presentinvention. As illustrated in FIG. 2, the transmission processing unit107 is configured to include a plurality of physical downlink sharedchannel processing units 201-1 to 201-M (hereinafter, denoted by thephysical downlink shared channel processing unit 201 including thephysical downlink shared channel processing units 201-1 to 201-M), aplurality of physical downlink control channel processing units 203-1 to203-M (hereinafter, denoted by the physical downlink control channelprocessing unit 203 including the physical downlink control channelprocessing units 203-1 to 203-M), a downlink pilot channel processingunit 205, a pre-coding processing unit 231, a multiplexing unit 207, anInverse Fast Fourier Transform (IFFT) unit 209, a Guard Interval (GI)insertion unit 211, a D/A (Digital/Analog converter; a digital-to-analogconversion) unit 213, a transmission Radio Frequency (RF) unit 215, anda transmit antenna 111. In addition, since each physical downlink sharedchannel processing unit 201 and each physical downlink control channelprocessing unit 203 respectively have the same configuration andfunction, one of them will be described as a representative thereof. Inaddition, for simplicity of explanation, it is assumed that the transmitantenna 111 is configured by a plurality of transmit antennas beingarranged.

Further, as illustrated in FIG. 2, each physical downlink shared channelprocessing unit 201 includes a turbo coding unit 219, a data modulationunit 221 and a pre-coding processing unit 229. Further, as illustratedin FIG. 2, each physical downlink control channel processing unit 203includes a convolutional coding unit 223, a QPSK modulation unit 225 anda pre-coding processing unit 227. The physical downlink shared channelprocessing unit 201 performs a baseband signal process for transmittinginformation data addressed to the mobile station apparatus 5 in an OFDMscheme. The turbo coding unit 219 performs a turbo coding for enhancingerror tolerance of data on the information data which is input in acoding rate which is input from the control unit 105, and outputs theinformation data to the data modulation unit 221. The data modulationunit 221 modulates the data coded by the turbo coding unit 219 by amodulation scheme which is input from the control unit 105, for example,modulation schemes such as a Quadrature Phase Shift Keying (QPSK), a 16Quadrature Amplitude Modulation (16QAM), and a 64 Quadrature AmplitudeModulation (64QAM) and generates a signal sequence of modulationsymbols. The data modulation unit 221 outputs the generated signalsequence to the pre-coding processing unit 229. The pre-codingprocessing unit 229 performs a pre-coding process (beamforming process)on signals which are input from the data modulation unit 221 and outputsthe signals to the multiplexing unit 207. Here, it is preferable thatthe pre-coding process perform phase rotation or the like on thegenerated signals such that the mobile station apparatus 5 efficientlyperforms reception (for example, such that reception power becomesmaximum and interference becomes minimum). In addition, when thepre-coding process is not performed on signals which are input from thedata modulation unit 221, the pre-coding processing unit 229 outputs thesignals which are input from the data modulation unit 221, as they are,to the multiplexing unit 207.

The physical downlink control channel processing unit 203 performs abaseband signal process for transmission in an OFDM scheme on the DCIwhich is input from the control unit 105. The convolutional coding unit223 performs a convolutional coding for enhancing error tolerance of theDCI based on a coding rate which is input from the control unit 105.Here, the DCI is controlled in units of bits. Further, the coding rateof the DCI which is transmitted in the second PDCCH is associated withthe eCCE aggregation number which is configured. Further, theconvolutional coding unit 223 performs a rate matching for adjusting thenumber of output bits for bits subjected to a convolutional codingprocess based on the coding rate which is input from the control unit105. The convolutional coding unit 223 outputs the coded DCI to the QPSKmodulation unit 225. The QPSK modulation unit 225 modulates the DCIwhich is coded by the convolutional coding unit 223 in a QPSK modulationscheme, and outputs the signal sequence of the modulation symbols whichare modulated to the pre-coding processing unit 227. The pre-codingprocessing unit 227 performs the pre-coding process on the signal whichis input from the QPSK modulation unit 225, and outputs the signal tothe multiplexing unit 207. In addition, the pre-coding processing unit227 outputs signals which are input from the QPSK modulation unit 225while not being subjected to the pre-coding process to the multiplexingunit 207.

The downlink pilot channel processing unit 205 generates downlinkreference signals (CRS, UE-specific RS, and CSI-RS) which are knownsignals for the mobile station apparatus 5 so as to be output to thepre-coding processing unit 231. The pre-coding processing unit 231outputs the CRS, and the CSI-RS which are input from the downlink pilotchannel processing unit 205 while not being subjected to the pre-codingprocess to the multiplexing unit 207. The pre-coding processing unit 231performs a pre-coding process on the UE-specific RS which is input fromthe downlink pilot channel processing unit 205, and outputs theUE-specific RS subjected to the multiplexing unit 207. For example, thepre-coding processing unit 231 performs the pre-coding process of thebeamforming process suitable for the mobile station apparatus 5 on theUE-specific RS. For example, the pre-coding processing unit 231 performsthe pre-coding process of the random beamforming process on theUE-specific RS. The pre-coding processing unit 231 performs the sameprocess as the process which has been performed on the PDSCH by thepre-coding processing unit 229 and/or the process which has beenperformed on the second PDCCH by the pre-coding processing unit 227 onthe UE-specific RS. More specifically, the pre-coding processing unit231 performs the pre-coding process on the eCCE signal, and performs thesame pre-coding process on UE-specific RS in which the eCCE and theantenna port are associated. Therefore, when the mobile stationapparatus 5 demodulates the second PDCCH signal to which the pre-codingprocess is applied, the UE-specific RS can be used in the estimation ofthe equalization channel including the fluctuation in the channel(transmission path) in the downlink and the phase rotation by thepre-coding processing unit 227. In other words, it is not necessary forthe base station apparatus 3 to notify the mobile station apparatus 5 ofinformation (phase rotation amount) of the pre-coding process by thepre-coding processing unit 227, and the mobile station apparatus 5 candemodulate the signal subjected to the pre-coding process.

The multiplexing unit 207 multiplexes signals which are input from thedownlink pilot channel processing unit 205, signals which are input fromeach physical downlink shared channel processing unit 201, and signalswhich are input from each physical downlink control channel processingunit 203 into the downlink subframe, according to an instruction fromthe control unit 105. The control signals regarding the allocation ofthe DL PRB pair for the PDSCH which is configured by the radio resourcecontrol unit 103, the allocation of the resources for the PDCCHs (thefirst PDCCH and the second PDCCH), and the resource mapping method ofeCCE of the second PDCCH are input to the control unit 105, and thecontrol unit 105 controls the process of the multiplexing unit 207 basedon the control signal. For example, the multiplexing unit 207multiplexes the second PDCCH signals to the downlink resource by theeCCE aggregation number which is configured by the radio resourcecontrol unit 103. The multiplexing unit 207 outputs the multiplexedsignals to the IFFT unit 209.

The IFFT unit 209 performs inverse fast Fourier transform and performsmodulation of an OFDM scheme on the signals multiplexed by themultiplexing unit 207, and outputs the signals to the GI insertion unit211. The GI insertion unit 211 generates a digital signal of a basebandconfigured with symbols in an OFDM scheme by inserting a guard intervalto the signal on which the IFFT unit 209 performs modulation of an OFDMscheme. As known already, the guard interval is generated by replicatinga portion of the top or end of the OFDM symbol to be transmitted. The GIinsertion unit 211 outputs the generated digital signal of a baseband tothe D/A unit 213. The D/A unit 213 converts the digital signal of abaseband which is input from the GI insertion unit 211 into an analogsignal and outputs the signals to the transmission RF unit 215. Thetransmission RF unit 215 generates the in-phase component and theorthogonal component of the intermediate frequency, from the analogsignal which is input from the D/A unit 213, and removes the excessfrequency component with respect to the intermediate frequency band.Next, the transmission RF unit 215 converts the signals of theintermediate frequency into the signals of a high frequency(up-convert), removes the excess frequency component, amplifies thepower, and transmits the signals to the mobile station apparatus 5through the transmit antenna 111.

<Configuration of Reception Processing Unit 101 of Base StationApparatus 3>

Hereinafter, the details of the reception processing unit 101 of thebase station apparatus 3 will be described. FIG. 3 is a schematic blockdiagram showing a configuration of the reception processing unit 101 ofthe base station apparatus 3 according to the embodiment of the presentinvention. As illustrated in FIG. 3, the reception processing unit 101is configured to include a reception RF unit 301, an A/D (Analog/Digitalconverter; analog-to-digital conversion) unit 303, a symbol timingdetection unit 309, a GI removing unit 311, a FFT unit 313, a subcarrierdemapping unit 315, a channel estimation unit 317, a PUSCH channelequalization unit 319, a PUCCH channel equalization unit 321, an IDFTunit 323, a data demodulation unit 325, a turbo decoding unit 327, aphysical uplink control channel detection unit 329, a preamble detectionunit 331, and a SRS processing unit 333.

The reception RF unit 301 appropriately amplifies the signals which arereceived in the receive antenna 109, converts the amplified signals tosignals of the intermediate frequency (down-convert), removes theunnecessary frequency component, controls the amplification level so asto appropriately maintain the signal level, and performs orthogonaldemodulation, based on the in-phase component and the quadrature-phasecomponent of the received signals. The reception RF unit 301 outputs theanalog signal subjected to the orthogonal demodulation, to the A/D unit303. The A/D unit 303 converts the analog signal subjected to theorthogonal demodulation by the reception RF unit 301 into the digitalsignal, and outputs the converted digital signal to the symbol timingdetection unit 309 and the GI removing unit 311.

The symbol timing detection unit 309 detects the timing of the symbol,based on the signals which are input by the A/D unit 303, and outputs acontrol signal indicating a timing of the detected symbol boundary tothe GI removing unit 311. The GI removing unit 311 removes a portioncorresponding to the guard interval from signals which are input by theA/D unit 303, based on the control signal from the symbol timingdetection unit 309, and outputs the signal of a remaining part to theFFT unit 313. The FFT unit 313 performs fast Fourier transform onsignals which are input from the GI removing unit 311, performsdemodulation of a DFT-Spread-OFDM scheme and outputs the signals to thesubcarrier demapping unit 315. In addition, the number of points of theFFT unit 313 is the same as the number of points of the IFFT unit of themobile station apparatus 5 described later.

The subcarrier demapping unit 315 separates the signals demodulated bythe FFT unit 313 into a DM RS, a SRS, a signal of the PUSCH and a signalof the PUCCH, based on the control signal which is input from thecontrol unit 105. The subcarrier demapping unit 315 outputs theseparated DM RS to the channel estimation unit 317, the separated SRS tothe SRS processing unit 333, the separated signals of the PUSCH to thePUSCH channel equalization unit 319, and the separated PUCCH signals tothe PUCCH channel equalization unit 321.

The channel estimation unit 317 estimates the change in the channelusing the DM RS separated by the subcarrier demapping unit 315 and theknown signal. The channel estimation unit 317 outputs the estimatedchannel estimation value to the PUSCH channel equalization unit 319 andthe PUCCH channel equalization unit 321. The PUSCH channel equalizationunit 319 equalizes the amplitude and the phase of the PUSCH signal whichis separated by the subcarrier demapping unit 315 based on the channelestimation value which is input from the channel estimation unit 317.Here, the equalization represents a process to restore the change in thechannel that the signal receives during the wireless communication. ThePUSCH channel equalization unit 319 outputs the adjusted signal to theIDFT unit 323.

The IDFT unit 323 performs an inverse discrete Fourier transform on thesignals which are input from the PUSCH channel equalization unit 319 andoutputs the transformed signals to the data demodulation unit 325. Thedata demodulation unit 325 demodulates the PUSCH signals which areconverted by the IDFT unit 323, and outputs the demodulated PUSCH signalto the turbo decoding unit 327. The demodulation is the demodulationcorresponding to a modulation scheme used in the data modulation unit ofthe mobile station apparatus 5, and the modulation scheme is input bythe control unit 105. The turbo decoding unit 327 decodes informationdata from the PUSCH signal which is input from the data demodulationunit 325 and demodulated. The coding rate is input by the control unit105.

The PUCCH channel equalization unit 321 equalizes the amplitude and thephase of the PUCCH signal which is separated by the subcarrier demappingunit 315 based on the channel estimation value which is input from thechannel estimation unit 317. The PUCCH channel equalization unit 321outputs the equalized signal to the physical uplink control channeldetection unit 329.

The physical uplink control channel detection unit 329 demodulates anddecodes the signals which are input from the PUCCH channel equalizationunit 321 so as to detect a UCI. The physical uplink control channeldetection unit 329 performs separation of the code-multiplexed signalsin the frequency domain and/or the time domain. The physical uplinkcontrol channel detection unit 329 performs a process to detect theACK/NACK, the SR, and the CQI from the code-multiplexed PUCCH signals inthe frequency domain and/or the time domain, using the code sequenceused on the transmission side. Specifically, the physical uplink controlchannel detection unit 329 multiplies the signal for each subcarrier ofthe PUCCH by each code of a code sequence and combines signalsmultiplied by each code, as a detection process using the code sequencein the frequency domain, that is, a process to separate thecode-multiplexed signals in the frequency domain. Specifically, thephysical uplink control channel detection unit 329 multiplies the signalfor each SC-FDMA symbol of the PUCCH by each code of a code sequence andcombines signals multiplied by each code, as a detection process usingthe code sequence in the time domain, that is, a process to separate thecode-multiplexed signals in the time domain. In addition, the physicaluplink control channel detection unit 329 configures a detection processfor the PUCCH signal based on the control signal from the control unit105.

The SRS processing unit 333 measures the channel quality using the SRSwhich is input from the subcarrier mapping unit 315 in the subcarrier,and outputs the measurement result of the channel quality of the UL PRB(UL PRB pair) to the control unit 105. The control unit 105 instructsthe SRS processing unit 333 from which uplink subframe and from which ULPRB (UL PRB pair) signals are to be measured for the channel quality ofthe mobile station apparatus 5. Further, the SRS processing unit 333detects the synchronization deviation of the uplink using the SRS whichis input from the subcarrier mapping unit 315 in the subcarrier, andoutputs information (synchronization deviation information) indicatingthe synchronization deviation of the uplink to the control unit 105. Inaddition, the SRS processing unit 333 may perform a process to detectthe synchronization deviation of the uplink from the reception signal inthe time domain. The specific process may perform the same process asthe process performed in the preamble detection unit 331 describedlater.

The preamble detection unit 331 performs a process to detect (receive)the preamble transmitted for the reception signal corresponding to thePRACH, based on the signal which is input by the A/D unit 303.Specifically, the preamble detection unit 331 performs a correlationprocess with the replica signal which may be transmitted and isgenerated using each preamble sequence, for the reception signals ofvarious timings within the guard time. For example, when the correlationvalue is higher than a threshold that is configured in advance, thepreamble detection unit 331 determines that the same signal as thepreamble sequence used in the generation of the replica signal used inthe correlation process is transmitted from the mobile station apparatus5. Then, the preamble detection unit 331 determines the timing havingthe highest correlation value as the arrival timing of the preamblesequence. Then, the preamble detection unit 331 generates preambledetection information including at least information indicating thedetected preamble sequence and information indicating the arrival timingand outputs the information to the control unit 105.

The control unit 105 performs control of the subcarrier demapping unit315, the data demodulation unit 325, the turbo decoding unit 327, thechannel estimation unit 317, and the physical uplink control channeldetection unit 329, based on the control information (DCI) which istransmitted to the mobile station apparatus 5 using the PDCCH by thebase station apparatus 3 and the control information (RRC signaling)which is transmitted using the PDSCH. Further, the control unit 105ascertains with which resource (the uplink subframe, the UL PRB (UL PRBpair), the code sequence of the frequency domain, and the code sequenceof the time domain) the PRACH, the PUSCH, the PUCCH, and the SRS whichhave been transmitted (having a possibility of being transmitted) byeach mobile station apparatus 5 is configured, based on the controlinformation transmitted to the mobile station apparatus 5 by the basestation apparatus 3.

<Overall Configuration of Mobile Station Apparatus 5>

Hereinafter, the configuration of the mobile station apparatus 5according to the present embodiment will be described using FIGS. 4 to6. FIG. 4 is a schematic block diagram showing the configuration of amobile station apparatus 5 according to the embodiment of the presentinvention. As illustrated in FIG. 4, the mobile station apparatus 5 isconfigured to include a reception processing unit (a first receptionprocessing unit) 401, a radio resource control unit (a first radioresource control unit) 403, a control unit (a first control unit) 405,and a transmission processing unit (a first transmission processingunit) 407.

The reception processing unit 401 receives signals from the base stationapparatus 3, and demodulates and decodes the reception signal accordingto the instruction of the control unit 405. When the signals of thePDCCH (the first PDCCH and the second PDCCH) addressed to the mobilestation apparatus 5 are detected, the reception processing unit 401outputs the DCI obtained by decoding the PDCCH signal to the controlunit 405. For example, the reception processing unit 401 performs aprocess to detect the second PDCCH addressed to the mobile stationapparatus 5 in the search space within the second PDCCH region which isdesignated from the base station apparatus 3. For example, the receptionprocessing unit 401 performs a process of configuring a search space forthe candidate of the eCCE aggregation number and detecting the secondPDCCH addressed to the mobile station apparatus 5. For example, thereception processing unit 401 performs estimation of the channel byusing the UE-specific RS in the second PDCCH region which is designatedby the base station apparatus 3, performs demodulation of the secondPDCCH signal, and performs a process of detecting signals including thecontrol information addressed to the mobile station apparatus 5. Forexample, the reception processing unit 401 performs demodulation ofsecond PDCCH signals by using the UE-specific RS of the antenna portcorresponding to eCCEs or eREGs configuring the ePDCCH candidate forperforming the detection process.

Further, the reception processing unit 401 outputs information dataobtained by decoding the PDSCH addressed to the mobile station apparatus5 to a higher layer through the control unit 405, based on theinstruction of the control unit 405 after the DCI included in the PDCCHis output to the control unit 405. The downlink assignment among the DCIincluded in the PDCCH includes information indicating the allocation ofthe PDSCH resource. Further, the reception processing unit 401 outputsthe control information, which is obtained by decoding the PDSCH and isgenerated in the radio resource control unit 103 of the base stationapparatus 3, to the control unit 405, and outputs control information tothe radio resource control unit 403 of the mobile station apparatus 5through the control unit 405. For example, the control informationgenerated by the radio resource control unit 103 of the base stationapparatus 3 includes information indicating DL PRB pair of the secondPDCCH region, information indicating a resource mapping method of eCCEof each second PDCCH region, and information indicating a PUCCH resourceoffset for each second PDCCH region.

Further, the reception processing unit 401 outputs informationindicating the second PDCCH region from which the second PDCCH isdetected and information indicating the eCCEs configuring the detectedsecond PDCCH, to the control unit 405.

Further, the reception processing unit 401 outputs the Cyclic RedundancyCheck (CRC) code included in the PDSCH to the control unit 405. Althoughit is not described in the description of the base station apparatus 3,the transmission processing unit 107 of the base station apparatus 3generates the CRC code from the information data and transmits theinformation data and the CRC code in the PDSCH. The CRC code is used inthe mobile station apparatus 5 to determine whether data that isincluded in the PDSCH is incorrect, or is not incorrect. For example,when information generated from the data by using a generator polynomialwhich is determined in advance in the mobile station apparatus 5 and aCRC code which is generated in the base station apparatus 3 and istransmitted in the PDSCH are the same, it is determined that data is notincorrect. When information generated from the data by using a generatorpolynomial which is determined in advance in the mobile stationapparatus 5 and a CRC code which is generated in the base stationapparatus 3 and is transmitted in the PDSCH are different, it isdetermined that data is incorrect.

Further, the reception processing unit 401 measures reception quality ofthe downlink (Reference Signal Received Power (RSRP)), and outputs themeasurement result to the control unit 405. The reception processingunit 401 measures (calculates) the RSRP from the CRS or the CSI-RS,based on the instruction from the control unit 405. The details of thereception processing unit 401 will be described later.

The control unit 405 confirms data which is transmitted from the basestation apparatus 3 using the PDSCH, and is input by the receptionprocessing unit 401, outputs the information data among data to thehigher layer, and controls the reception processing unit 401 and thetransmission processing unit 407, based on the control informationgenerated in the radio resource control unit 103 of the base stationapparatus 3 among data. Further, the control unit 405 controls thereception processing unit 401 and the transmission processing unit 407,based on the instruction from the radio resource control unit 403. Forexample, the control unit 405 controls the reception processing unit 401so as to perform a process to detect the second PDCCH for the signalswithin the DL PRB pair of the second PDCCH region which is instructedfrom the radio resource control unit 403. For example, the control unit405 controls the reception processing unit 401 so as to performdemapping of the eCCE resource of the second PDCCH region, based on theinformation indicating a method of eCCE resource mapping of the secondPDCCH region which is instructed from the radio resource control unit403. Here, the demapping of the eCCE resource of the second PDCCH regionmeans, for example, as illustrated in FIGS. 20 and 21, a process ofconfiguring (forming, building, and creating) second PDCCH candidates tobe subjected to a detection process from the signals within the secondPDCCH region. Further, the control unit 405 controls a region forperforming a process to detect the second PDCCH within the second PDCCHregion for the reception processing unit 401. Specifically, the controlunit 405 indicates (configures) the eCCE aggregation number forconfiguring the search space for each second PDCCH region, and secondPDCCH candidates for performing a process of detecting the second PDCCHin the second PDCCH region, to the reception processing unit 401 foreach eCCE aggregation number. Further, the control unit 405 controls thereception processing unit 401 so as to use the UE-specific RS of theantenna port corresponding to the demodulation of each eCCE signal.

The control unit 405 configures the PUCCH resource offset for eachsecond PDCCH region, based on the instruction from the radio resourcecontrol unit 403. The control unit 405 determines and selects theresource (PUCCH resource index) of the ACK/NACK PUCCH for transmittingthe ACK/NACK for the PDSCH of which resource allocation is performed bythe second PDCCH, based on the information indicating the second PDCCHregion from which the second PDCCH is detected, information indicatingeCCE (eCCE index), and a PUCCH resource offset for each second PDCCHregion which is configured, which are input from the receptionprocessing unit 401 so as to control the transmission processing unit407.

Further, the control unit 405 controls the reception processing unit 401and the transmission processing unit 407, based on the DCI which istransmitted from the base station apparatus 3 by using the PDCCH andinput by the reception processing unit 401. Specifically, the controlunit 405 controls the reception processing unit 401 mainly based on thedetected downlink assignment, and controls the transmission processingunit 407 mainly based on the detected uplink grant. Further, the controlunit 405 controls the transmission processing unit 407, based on thecontrol information indicating the transmission power control command ofthe PUCCH included in the downlink assignment. The control unit 405compares information generated by using a generator polynomial which isdetermined in advance from the data which is input from the receptionprocessing unit 401 with a CRC code which is input from the receptionprocessing unit 401, determines whether data is incorrect or not, andgenerates ACK/NACK. The generated ACK/NACK is transmitted from thetransmission processing unit 407. Further, the control unit 405generates SR and CQI, based on the instruction from the radio resourcecontrol unit 403. Further, the control unit 405 controls thetransmission timing of the signal of the transmission processing unit407, based on the adjustment value of the uplink transmission timingthat has been notified from the base station apparatus 3. Further, thecontrol unit 405 controls the transmission processing unit 407 so as totransmit the information indicating the reception quality (RSRP) of thedownlink which is input by the reception processing unit 401.

The radio resource control unit 403 stores and holds control informationwhich is generated in the radio resource control unit 103 of the basestation apparatus 3, and notified by the base station apparatus 3, andperforms control of the reception processing unit 401 and thetransmission processing unit 407 through the control unit 405. In otherwords, the radio resource control unit 403 has a memory function ofholding various parameters. For example, the radio resource control unit403 holds information regarding the DL PRB pair of the second PDCCHregion, information regarding the resource mapping method of eCCE of thesecond PDCCH region, and information regarding a PUCCH resource offsetfor each second PDCCH region, and outputs various control signals to thecontrol unit 405. The radio resource control unit 403 holds parametersrelated to the transmission power of the PUSCH, the PUCCH, the SRS, andthe PRACH, and outputs the control signal to the control unit 405 so asto use the parameters notified by the base station apparatus 3.

The radio resource control unit 403 sets values of parameters related tothe transmission power such as the PUCCH, the PUSCH, the SRS, and thePRACH. The value of transmission power which is configured in the radioresource control unit 403 is output by the control unit 405 to thetransmission processing unit 407. In addition, the DM RS configured withthe resource within the same UL PRB as the PUCCH is subjected to thesame transmission power control as the PUCCH. In addition, the DM RSconfigured with the resource within the same UL PRB as the PUSCH issubjected to the same transmission power control as the PUSCH. The radioresource control unit 403 sets values such as a parameter based on thenumber of UL PRB pairs allocated to the PUSCH, the cell-specific andmobile station apparatus-specific parameters which are notified inadvance by the base station apparatus 3, a parameter based on themodulation scheme used in the PUSCH, a parameter based on the estimatedpath-loss value, and a parameter based on the transmission power controlcommand notified by the base station apparatus 3, for the PUSCH. Theradio resource control unit 403 sets values such as a parameter based onthe signal configuration of PUCCH, the cell-specific and mobile stationapparatus-specific parameters which are notified in advance by the basestation apparatus 3, a parameter based on the estimated path-loss value,and a parameter based on the notified transmission power controlcommand, for the PUCCH.

In addition, as parameters related to the transmission power, thecell-specific and mobile station apparatus-specific parameters arenotified by the base station apparatus 3 using the PDSCH, and thetransmission power control command is notified by the base stationapparatus 3 using the PDCCH. The transmission power control command forthe PUSCH is included in the uplink grant, and the transmission powercontrol command for the PUCCH is included in the downlink assignment. Inaddition, various parameters which are notified by the base stationapparatus 3 and related to the transmission power are appropriatelystored in the radio resource control unit 403, and the stored value isinput to the control unit 405.

The transmission processing unit 407 transmits signals obtained bycoding and modulating the information data and the UCI, using theresources of the PUSCH and the PUCCH, to the base station apparatus 3through the transmit antenna 411, according to the instruction of thecontrol unit 405. Further, the transmission processing unit 407 sets thetransmission power of each of the PUSCH, the PUCCH, the SRS, the DM RS,and the PRACH according to an instruction of the control unit 405. Thedetails of the transmission processing unit 407 will be described later.

<Reception Processing Unit 401 of Mobile Station Apparatus 5>

Hereinafter, the details of the reception processing unit 401 of themobile station apparatus 5 will be described. FIG. 5 is a schematicblock diagram showing a configuration of a reception processing unit 401of the mobile station apparatus 5 according to the embodiment of thepresent invention. As illustrated in FIG. 5, the reception processingunit 401 is configured to include a reception RF unit 501, an A/D unit503, a symbol timing detection unit 505, a GI removing unit 507, a FFTunit 509, a demultiplexing unit 511, a channel estimation unit 513, aPDSCH channel compensation unit 515, a physical downlink shared channeldecoding unit 517, a PDCCH channel compensation unit 519, a physicaldownlink control channel decoding unit 521, a downlink reception qualitymeasurement unit 531, and a PDCCH demapping unit 533. Further, asillustrated in FIG. 5, the physical downlink shared channel decodingunit 517 includes a data demodulation unit 523 and a turbo decoding unit525. Further, as illustrated in FIG. 5, the physical downlink controlchannel decoding unit 521 includes a QPSK demodulation unit 527 and aViterbi decoder unit 529.

The reception RF unit 501 appropriately amplifies the signals which arereceived in the receive antenna 409, converts the amplified signals tosignals of the intermediate frequency (down-convert), removes theunnecessary frequency component, controls the amplification level so asto appropriately maintain the signal level, and performs orthogonaldemodulation, based on the in-phase component and the quadrature-phasecomponent of the received signals. The reception RF unit 501 outputs theanalog signal subjected to the orthogonal demodulation, to the A/D unit503.

The A/D unit 503 converts the analog signal subjected to the orthogonaldemodulation by the reception RF unit 501 into the digital signal, andoutputs the converted digital signal to the symbol timing detection unit505 and the GI removing unit 507. The symbol timing detection unit 505detects the timing of the symbol, based on the digital signal which isconverted by the A/D unit 503, and outputs a control signal indicatingthe detected timing of the symbol boundary to the GI removing unit 507.The GI removing unit 507 removes the portion corresponding to the guardinterval from the digital signal which is output by the A/D unit 503,based on the control signal from the symbol timing detection unit 505,and outputs the signals of the remaining parts to the FFT unit 509. TheFFT unit 509 performs fast Fourier transform and a demodulation of anOFDM scheme on the signals which are input from the GI removing unit507, and outputs the signals to the demultiplexing unit 511.

The demultiplexing unit 511 separates the signals demodulated by the FFTunit 509 into a signal of the PDCCH (first PDCCH and the second PDCCH)and the signal of the PDSCH, based on the control signal which is inputfrom the control unit 405. The demultiplexing unit 511 outputs theseparated signals of the PDSCH to the PDSCH channel compensation unit515, and outputs separated signals of the PDCCH to the PDCCH channelcompensation unit 519. For example, the demultiplexing unit 511 outputsthe signals of the second PDCCH of the second PDCCH region which isdesignated to the mobile station apparatus 5, to the PDCCH channelcompensation unit 519. Further, the demultiplexing unit 511 separatesthe downlink resource element in which the downlink reference signal isallocated, and outputs the downlink reference signal (CRS andUE-specific RS) to the channel estimation unit 513. For example, thedemultiplexing unit 511 outputs the UE-specific RS of the second PDCCHregion designated to the mobile station apparatus 5, to the channelestimation unit 513. Further, the demultiplexing unit 511 outputs thedownlink reference signal (CRS and CSI-RS) to the downlink receptionquality measurement unit 531.

The channel estimation unit 513 estimates the change in the channel byusing the downlink reference signal separated by the demultiplexing unit511 and known signals, and outputs the channel compensation value foradjusting the amplitude and the phase in order to compensate for thechange in the channel, to the PDSCH channel compensation unit 515 andthe PDCCH channel compensation unit 519. The channel estimation unit 513estimates independently the change in the channel by respectively usingthe CRS and the UE-specific RS, and outputs the estimated change. Forexample, the channel estimation unit 513 generates a channelcompensation value from the channel estimation value which is estimatedby using the UE-specific RS allocated in a plurality of DL PRB pairswithin the second PDCCH region designated to the mobile stationapparatus 5, and outputs the generated value to the PDCCH channelcompensation unit 519. Further, the channel estimation unit 513 performsthe channel estimation and the generation of channel compensation value,by using the UE-specific RS for each of one or more antenna ports whichare designed from the control unit 405. For example, the channelestimation unit 513 generates a channel compensation value from thechannel estimation value which is estimated by using the UE-specific RSwhich is allocated to the mobile station apparatus 5 and allocated in aplurality of DL PRB pairs allocated to PDSCH, and outputs the generatedvalue to the PDSCH channel compensation unit 515. For example, thechannel estimation unit 513 generates a channel compensation value fromthe channel estimation value which is estimated using the CRS, andoutputs the generated value to the PDCCH channel compensation unit 519.For example, the channel estimation unit 513 generates a channelcompensation value from the channel estimation value which is estimatedusing the CRS, and outputs the generated value to the PDSCH channelcompensation unit 515.

The PDSCH channel compensation unit 515 adjusts the amplitude and thephase of the PDSCH signals which are separated by the demultiplexingunit 511 according to the channel compensation value which is input fromthe channel estimation unit 513. For example, the PDSCH channelcompensation unit 515 adjusts the signals of a certain PDSCH accordingto the channel compensation value generated based on the UE-specific RSin the channel estimation unit 513, and adjusts the signals of adifferent PDSCH according to the channel compensation value generatedbased on the CRS in the channel estimation unit 513. The PDSCH channelcompensation unit 515 outputs the signals of which channel is adjustedto the data demodulation unit 523 of the physical downlink sharedchannel decoding unit 517.

The physical downlink shared channel decoding unit 517 performsdemodulation and decoding of the PDSCH, based on the instruction fromthe control unit 405 and detects information data. The data demodulationunit 523 performs demodulation of the signals of the PDSCH which areinput from the channel compensation unit 515, and outputs thedemodulated signals of the PDSCH to the turbo decoding unit 525. Thedemodulation is a demodulation corresponding to the modulation schemeused in the data modulation unit 221 of the base station apparatus 3.The turbo decoding unit 525 decodes information data from thedemodulated signals of the PDSCH which are input from the datademodulation unit 523, and outputs the decoded information data to thehigher layer through the control unit 405. In addition, controlinformation which is transmitted using the PDSCH and is generated in theradio resource control unit 103 of the base station apparatus 3, and thelike is output to the control unit 405, and is output also to the radioresource control unit 403 through the control unit 405. In addition, theCRC code included in the PDSCH is also output to the control unit 405.

The PDCCH channel compensation unit 519 adjusts the amplitude and thephase of the PDCCH signals which are separated by the demultiplexingunit 511 according to the channel compensation value which is input fromthe channel estimation unit 513. For example, the PDCCH channelcompensation unit 519 adjusts the signals of the second PDCCH accordingto the channel compensation value generated based on the UE-specific RSin the channel estimation unit 513, and adjusts the signals of the firstPDCCH according to the channel compensation value generated based on theCRS in the channel estimation unit 513. For example, the PDCCH channelcompensation unit 519 adjusts the eCCE signals, according to the channelcompensation value which has been generated based on the UE-specific RSof the antenna port corresponding to the eCCE. For example, PDCCHchannel compensation unit 519 adjusts the eCCE signals, according to thechannel compensation value which has been generated based on theUE-specific RS of the antenna port corresponding to the eREG configuringthe eCCE. The PDCCH channel compensation unit 519 outputs the adjustedsignals to the PDCCH demapping unit 533.

The PDCCH demapping unit 533 performs a demapping for the first PDCCH ora demapping for the second PDCCH, on the signals which are input fromthe PDCCH channel compensation unit 519. In addition, the PDCCHdemapping unit 533 performs a demapping for the Localized mapping or ademapping for the Distributed mapping on the signals of the second PDCCHwhich are input from the PDCCH channel compensation unit 519. The PDCCHdemapping unit 533 converts the signals of the first PDCCH which areinput into signals in a unit of a CCE as described using FIG. 17 suchthat a process in a unit of a CCE illustrated in FIG. 16 is performedfor the signals of the first PDCCH which are input, in the physicaldownlink control channel decoding unit 521. The PDCCH demapping unit 533converts the signals of the second PDCCH which are input into signals ina unit of the eCCE such that a process in a unit of the eCCE illustratedin FIG. 19 is performed for the signals of the second PDCCH which areinput, in the physical downlink control channel decoding unit 521. ThePDCCH demapping unit 533 converts the signals of the second PDCCH of thesecond PDCCH region, which are input, and to which the Localized mappingis applied into signals of a unit of the eCCE, as described using FIG.20. The PDCCH demapping unit 533 converts the signals of the secondPDCCH of the second PDCCH region, which are input, to which theDistributed mapping is applied into signals of a unit of the eCCE, asdescribed using FIG. 21. The PDCCH demapping unit 533 outputs theconverted signals to the QPSK demodulation unit 527 of the physicaldownlink control channel decoding unit 521.

The physical downlink control channel decoding unit 521 performsdemodulation and decoding on the signals which are input from the PDCCHchannel compensation unit 519 as below, and detects the control data.The QPSK demodulation unit 527 performs QPSK demodulation on the signalsof the PDCCH, and outputs the signals to the Viterbi decoder unit 529.The Viterbi decoder unit 529 decodes the signals demodulated by the QPSKdemodulation unit 527, and outputs the decoded DCI to the control unit405. Here, the signal is represented in a unit of a bit, and the Viterbidecoder unit 529 performs a rate dematching for adjusting the number ofbits for performing a Viterbi decoding process on the input bits. Inaddition, when the detected control data is output to the control unit405, the physical downlink control channel decoding unit 521 outputs theinformation indicating the region of the second PDCCH from which thecontrol data is detected and information indicating the eCCE to thecontrol unit 405.

First, a detection process for the first PDCCH will be described. Themobile station apparatus 5 assumes a plurality of CCE aggregationnumbers, and performs a process to detect a DCI addressed to the mobilestation apparatus 5. The mobile station apparatus 5 performs a differentdecoding process on the signal of the first PDCCH for each assumed CCEaggregation number (coding rate), and obtains a DCI included in thefirst PDCCH in which an error is not detected in the CRC code added tothe first PDCCH with the DCI. Such a process is referred to as a blinddecoding. In addition, the mobile station apparatus 5 does not performthe blind decoding in which the first PDCCH is assumed on the signals(reception signals) of all CCEs (REG) of the downlink system band butperforms the blind decoding on only some CCE. Some CCE (CCEs) on whichthe blind decoding is performed is referred to as a search space (searchspace for the first PDCCH). Further, different search spaces (searchspace for the first PDCCH) are defined for each CCE aggregation number.In the communication system 1 according to an embodiment of the presentinvention, respective different search spaces (search space for firstPDCCH) are configured for the first PDCCH in the mobile stationapparatus 5. Here, the search space (search space for the first PDCCH)for the first PDCCH of each mobile station apparatus 5 may be configuredwith all different CCE (CCEs), may be configured with all the same CCE(CCEs), and may be configured with a partially overlapping CCE (CCEs).

Next, a detection process for the second PDCCH will be described. Themobile station apparatus 5 assumes a plurality of eCCE aggregationnumbers, and performs a process to detect a DCI addressed to the mobilestation apparatus 5. The mobile station apparatus 5 performs a differentdecoding process on the signal of the second PDCCH for each assumed eCCEaggregation number (coding rate), and obtains a DCI included in thesecond PDCCH in which an error is not detected in the CRC code added tothe second PDCCH with the DCI. Such a process is referred to as a blinddecoding. In addition, the mobile station apparatus 5 does not performthe blind decoding in which the second PDCCH is assumed on the signalsof all eCCEs (reception signal) of the second PDCCH region configured bythe base station apparatus 3, but performs the blind decoding on onlysome eCCEs. Some eCCE (eCCEs) on which the blind decoding is performedis referred to as a search space (search space for the second PDCCH).Further, different search spaces (search space for the second PDCCH) aredefined for each eCCE aggregation number. In the mobile stationapparatus 5 in which a plurality of second PDCCH regions are configured,the search spaces are configured (configured and defined) in respectiveconfigured second PDCCH regions. In the mobile station apparatus 5, thesearch spaces are configured for the second PDCCH region to which theDistributed mapping is applied and the second PDCCH region to which theLocalized mapping is applied. In the mobile station apparatus 5 in whicha plurality of second PDCCH regions are configured, a plurality ofsearch spaces are simultaneously configured in a certain downlinksubframe.

In the communication system 1 according to an embodiment of the presentinvention, with respect to the second PDCCH, a plurality of differentsearch spaces (search space for the second PDCCH) are configured in themobile station apparatus 5. Here, the search space (search space for thesecond PDCCH) for the second PDCCH of each mobile station apparatus 5 inwhich the same second PDCCH region is configured may be configured withall different eCCE (eCCEs), may be configured with all the same eCCE(eCCEs), and may be configured with a partially overlapping eCCE(eCCEs).

In the mobile station apparatus 5 in which a plurality of second PDCCHregions are configured, search spaces (search space for the secondPDCCH) are configured in each second PDCCH region. The search space(search space for the second PDCCH) means a logical region in which themobile station apparatus 5 performs decoding detection of the secondPDCCH within the second PDCCH region. The search space (search space forthe second PDCCH) is configured with a plurality of second PDCCHcandidates. The second PDCCH candidates are to be subjected to thedecoding detection of the second PDCCH by the mobile station apparatus5. For each eCCE aggregation number, different second PDCCH candidatesare configured with different eCCEs (including one eCCE and a pluralityof eCCEs). For example, the base station apparatus 3 notifies the mobilestation apparatus 5 of the eCCE or the second PDCCH candidate used inthe search space (search space for the second PDCCH), using RRCsignaling.

The number of second PDCCH candidates may be different in respectivesearch spaces of a plurality of second PDCCH regions. Further, in acertain eCCE aggregation number, the number of second PDCCH candidatesof the search space of respective second PDCCH regions may be the same,and in a different eCCE aggregation number, the number of second PDCCHcandidates of the search space of respective second PDCCH regions may bedifferent. Further, the second PDCCH candidate of a certain eCCEaggregation number may be configured in the search space of one secondPDCCH region, and may not be configured in the search space of the othersecond PDCCH region. Further, the number of second PDCCH candidates ofthe search space in one second PDCCH region may vary depending on thenumber of second PDCCH regions configured in the mobile stationapparatus 5.

In addition, the control unit 405 determines whether the DCI which isinput from the Viterbi decoder unit 529 has no error and is a DCIaddressed to the mobile station apparatus or not, and when it isdetermined that there is no error and it is the DCI addressed to themobile station apparatus 5, the control unit 405 controls thedemultiplexing unit 511, the data demodulation unit 523, the turbodecoding unit 525, and the transmission processing unit 407, based onthe DCI. For example, when the DCI is downlink assignment, the controlunit 405 controls the reception processing unit 401 so as to decode thesignal of the PDSCH. In addition, similar to the PDSCH, even in thePDCCH, a CRC code is included and the control unit 405 determineswhether the DCI of the PDCCH has an error or not using the CRC code.

The downlink reception quality measurement unit 531 measures receptionquality (RSRP) of the downlink of the cell, using the downlink referencesignal (CRS and CSI-RS), and outputs the measured reception qualityinformation of the downlink to the control unit 405. Further, thedownlink reception quality measurement unit 531 performs temporarychannel quality measurement for generating the CQI to be notified to thebase station apparatus 3 in the mobile station apparatus 5. The downlinkreception quality measurement unit 531 outputs information such as themeasured RSRP to the control unit 405.

<Transmission Processing Unit 407 of Mobile Station Apparatus 5>

FIG. 6 is a schematic block diagram showing a configuration of atransmission processing unit 407 of the mobile station apparatus 5according to the embodiment of the present invention. As illustrated inFIG. 6, the transmission processing unit 407 is configured to include aturbo coding unit 611, a data modulation unit 613, a DFT unit 615, anuplink pilot channel processing unit 617, a physical uplink controlchannel processing unit 619, a subcarrier mapping unit 621, an IFFT unit623, a GI insertion unit 625, a transmission power adjustment unit 627,a random access channel processing unit 629, a D/A unit 605, atransmission RF unit 607, and a transmit antenna 411. The transmissionprocessing unit 407 performs coding and modulation on the informationdata and the UCI, generates signals to be transmitted using the PUSCHand the PUCCH, and adjusts transmission power of the PUSCH and thePUCCH. The transmission processing unit 407 generates signals using thePRACH, and adjusts transmission power of the PRACH. The transmissionprocessing unit 407 generates a DM RS and a SRS, and adjuststransmission power of the DM RS and the SRS.

The turbo coding unit 611 performs a turbo coding for enhancing errortolerance of the data on the information data which is input in a codingrate which is instructed from the control unit 405, and output theinformation data to the data modulation unit 613. The data modulationunit 613 modulates the code data which is coded by the turbo coding unit611 by a modulation scheme which is instructed from the control unit405, for example, modulation schemes such as the QPSK, the 16QAM, andthe 64QAM, and generates a signal sequence of modulation symbols. Thedata modulation unit 613 outputs the generated signal sequence ofmodulation symbols to the DFT unit 615. The DFT unit 615 performs adiscrete Fourier transform on the signals which are output by the datamodulation unit 613 and outputs the transformed signals to thesubcarrier mapping unit 621.

The physical uplink control channel processing unit 619 performs abaseband signal process for transmitting a UCI which is input from thecontrol unit 405. The UCI which is input to the physical uplink controlchannel processing unit 619 is the ACK/NACK, the SR, and the CQI. Thephysical uplink control channel processing unit 619 outputs thegenerated signals to the subcarrier mapping unit 621 while beingsubjected to the baseband signal process. The physical uplink controlchannel processing unit 619 generates signals by coding the informationbit of the UCI.

Further, the physical uplink control channel processing unit 619performs a signal process related to the code multiplexing of thefrequency domain and/or the code multiplexing of the time domain on thesignals generated from the UCI. For example, the UL PRB pair, the codesequence in the frequency domain, and the code sequence in the timedomain, which are used for signals generated from the ACK/NACK areindicated to the physical uplink control channel processing unit 619from the control unit 405. The physical uplink control channelprocessing unit 619 multiplies the signal of the PUCCH generated fromthe information bit of ACK/NACK, the information bit of SR, or theinformation bit of CQI by a code sequence instructed from the controlunit 405 in order to realize a code multiplexing of the frequencydomain. The physical uplink control channel processing unit 619multiplies the signal of the PUCCH generated from the information bit ofACK/NACK, or the information bit of SR, by a code sequence instructedfrom the control unit 405 in order to realize a code multiplexing of thetime domain.

The uplink pilot channel processing unit 617 generates the SRS and theDM RS which are known signals in the base station apparatus 3 based onthe instruction from the control unit 405, and outputs the generatedsignals to the subcarrier mapping unit 621.

The subcarrier mapping unit 621 places the signals which are input fromthe uplink pilot channel processing unit 617, the signals which areinput from the DFT unit 615, and the signals which are input from thephysical uplink control channel processing unit 619 in the subcarrieraccording to the instruction from the control unit 405 so as to beoutput to the IFFT unit 623.

The IFFT unit 623 performs inverse fast Fourier transform on the signalswhich are output by the subcarrier mapping unit 621, and outputs thesignals to the GI insertion unit 625. Here, the number of points of theIFFT unit 623 is greater than the number of points of the DFT unit 615.The mobile station apparatus 5 performs demodulation of aDFT-Spread-OFDM scheme on signals which are transmitted using the PUSCH,by using the DFT unit 615, the subcarrier mapping unit 621, and the IFFTunit 623. The GI insertion unit 625 adds the guard interval to thesignals which are input from the IFFT unit 623, and outputs the signalsto the transmission power adjustment unit 627.

The random access channel processing unit 629 generates signalstransmitted on the PRACH by using a preamble sequence instructed fromthe control unit 405, and outputs the generated signals to thetransmission power adjustment unit 627.

The transmission power adjustment unit 627 adjusts the transmissionpower of the signals which are input from the GI insertion unit 625 orthe signals which are input from the random access channel processingunit 629, based on the control signal from the control unit 405, andoutputs the adjusted power to the D/A unit 605. In addition, thetransmission power adjustment unit 627 controls average transmissionpower of each of the PUSCH, the PUCCH, the DM RS, the SRS, and the PRACHfor each uplink subframe.

The D/A unit 605 converts the digital signal of a baseband which isinput from the transmission power adjustment unit 627 into an analogsignal and outputs the signals to the transmission RF unit 607. Thetransmission RF unit 607 generates the in-phase component and thequadrature-phase component of the intermediate frequency, from theanalog signal which is input from the D/A unit 605, and removes theexcess frequency component with respect to the intermediate frequencyband. Next, the transmission RF unit 607 converts the signals of theintermediate frequency into the signals of a high frequency(up-convert), removes the excess frequency component, amplifies thepower, and transmits the signals to the base station apparatus 3 throughthe transmit antenna 411.

FIG. 7 is a flowchart showing an example of a process regarding aconfiguration of a PUCCH resource offset for each second PDCCH region ofthe mobile station apparatus 5 according to the embodiment of thepresent invention. The mobile station apparatus 5 receives informationindicating a PUCCH resource offset for each second PDCCH region by usingRRC signaling from the base station apparatus 3 (step S101). Next, themobile station apparatus 5 configures a PUCCH resource offset for eachsecond PDCCH region, based on the information received from the basestation apparatus 3 (step S102).

FIG. 8 is a flowchart showing an example of a process regarding aconfiguring of PUCCH resource offset for each second PDCCH region of thebase station apparatus 3 according to the embodiment of the presentinvention. The base station apparatus 3 configures PUCCH resource offsetfor each second PDCCH region, based on the number of second PDCCHregions within a cell (step T101). Next, the base station apparatus 3configures such that information indicating PUCCH resource offset foreach second PDCCH region is transmitted to each mobile station apparatus5 (step T102).

As described above, in the embodiments of the present invention, in thecommunication system 1, a plurality of physical resource block pairs (DLPRB pairs) are configured as a downlink control channel region (secondPDCCH region) (ePDCCH region) (ePDCCH set) in which a downlink controlchannel (second PDCCH) (ePDCCH) may be allocated, a first element (eREG)is configured with a plurality of (for example, 16) resources into whichone physical resource block pair (DL PRB pair) is divided, a secondelement (eCCE) is configured with an aggregation (Localized mapped eCCE)of a plurality of (for example, 4) first elements (eREG) within onephysical resource block pair (DL PRB pair) or an aggregation(Distributed mapped eCCE) of a plurality of (for example, 4) firstelements (eREG) within a plurality of (for example, 4) physical resourceblock pairs (DL PRB pair), a downlink control channel (second PDCCH) isconfigured with an aggregation of one or more second elements (eCCE)(for example, an aggregation of 1, 2, 4, or 8 second elements), theresource of an uplink control channel (PUCCH) corresponds to each ofsecond elements (eCCE), and the base station apparatus 3 configures aplurality of downlink control channel regions (second PDCCH regions),the base station apparatus 3 configures the resource (PUCCH resourceoffset) of the uplink control channel in which the association with thesecond element (eCCE) of the downlink control channel region (secondPDCCH region) is started for each downlink control channel region(second PDCCH region), the base station apparatus 3 transmits theconfigured information to the mobile station apparatus 5, the mobilestation apparatus 5 configures a plurality of downlink control channelregions (second PDCCH regions) based on the information received fromthe base station apparatus 3, the mobile station apparatus 5 configuresthe resource (PUCCH resource offset) of the uplink control channel inwhich the association with the second element (eCCE) of the downlinkcontrol channel region (second PDCCH region) is started for eachdownlink control channel region (second PDCCH region), based oninformation received from the base station apparatus 3, for eachdownlink control channel region (second PDCCH region) which isconfigured. The mobile station apparatus 5 determines the identificationnumber (PUCCH resource index) of resources of an uplink control channel(PUCCH) used in transmission of reception confirmation acknowledgement(ACK/NACK) for the data (transport block) of the received downlinkshared channel (PDSCH), based on the identification number (eCCE index)of one or more second elements (eCCEs) configuring a downlink controlchannel (second PDCCH) including information of resource allocation of adownlink shared channel (PDSCH), and a resource (PUCCH resource offset)of an uplink control channel (PUCCH) in which the association with thesecond element (eCCE) of the downlink control channel region (secondPDCCH region) from which the downlink control channel (second PDCCH) isdetected is started.

Thus, it is possible to configure and use the PUCCH resource offset foreach second PDCCH region, such that it is possible to use differentACK/NACK PUCCH resources for the eCCEs of different second PDCCHregions, and prevent the different mobile station apparatuses for whichthe PDSCHs are allocated to the second PDCCH in different second PDCCHregions from using the same ACK/NACK PUCCH resource, in other words, itis possible to avoid the collision of the uplink signals between themobile station apparatuses 5. Further, the base station apparatus 3 canappropriately control the ACK/NACK PUCCH resources for dynamic ACK/NACKwhich are prepared in the uplink system band according to the number ofsecond PDCCH regions configured for a plurality of mobile stationapparatuses 5, and avoid an increase in the overhead on the ACK/NACKPUCCH of the uplink system band. If the eCCEs of the second PDCCH regionconfigured with DL PRB pairs are determined in advance according to theDL PRB pairs which are physically configured, and different ACK/NACKPUCCH resources are prepared for the eCCEs of the second PDCCH regionconfigured with DL PRB pairs which may all be DL PRB pairs, thecollision of the ACK/NACK signals between the mobile station apparatuses5 is avoided, but the overhead on the ACK/NACK PUCCH of the uplinksystem band is increased significantly. By using the embodiment of thepresent invention, it is possible to avoid the collision of ACK/NACKsignals between the mobile station apparatuses 5, while avoiding anincrease in uplink overhead.

In addition, in the embodiment of the present invention, a configurationhas been described in which information indicating a PUCCH resourceoffset for each second PDCCH region is explicitly and directly notifiedto the mobile station apparatus 5 from the base station apparatus 3 byusing RRC signaling, but a configuration may be used in which a PUCCHresource offset for each second PDCCH region is associated with theother information and the PUCCH resource offset for each second PDCCHregion is determined based on the other information in the mobilestation apparatus 5. For example, a number is given to the second PDCCHregion, a PUCCH resource offset is associated with the second PDCCHregion number, and the PUCCH resource offset for the second PDCCH regionis determined based on the number of the second PDCCH region in themobile station apparatus 5. Here, with respect to the second PDCCHregion number, a common number is used in an area managed by the basestation apparatus 3. For example, as illustrated in FIG. 25, when threesecond PDCCH regions (a second PDCCH region 1, a second PDCCH region 2,and a second PDCCH region 3) are configured in the downlink system band,a number is given to each of the second PDCCH regions, the number #0 isgiven to the second PDCCH region 1, the number #1 is given to the secondPDCCH region 2, and the number #2 is given to the second PDCCH region 3.When the second PDCCH region is configured in the mobile stationapparatus 5, the base station apparatus 3 notifies the mobile stationapparatus 5 of the given second PDCCH region number by using RRCsignaling.

The mobile station apparatus 5 calculates the PUCCH resource offset forthe second PDCCH region to which the second PDCCH region number isgiven, based on the given second PDCCH region number. Here, the mobilestation apparatus 5 calculates a PUCCH resource offset for the secondPDCCH region, by assuming that one second PDCCH region is configuredwith eCCEs of the number that has been determined in advance and PUCCHresources are reserved for each eCCE. For example, it is assumed that inthe mobile station apparatus 5, one second PDCCH region is configuredwith 16 eCCEs, and 16 PUCCH resources are reserved from the second PDCCHregion. The mobile station apparatus 5 recognizes that the second PDCCHregions of the smaller number than the given second PDCCH region numberare configured with any DL PRB pairs of downlink system band, andrecognizes that the PUCCH resource is reserved for the second PDCCHregions. Here, it is defined that the first ACK/NACK PUCCH resource forDynamic ACK/NACK is associated from the second PDCCH region having thesecond PDCCH region number #0. In other words, in FIG. 25, Offset X1 isused as the PUCCH resource offset for the second PDCCH region 1 havingthe second PDCCH region number #0, and in this manner, the mobilestation apparatus 5 recognizes the PUCCH resource offset. The Offset X2which is the PUCCH resource offset used in the second PDCCH region 2having the second PDCCH region number #1 is obtained by adding Offset X1to 16 which is the number of ACK/NACK PUCCH resources which are reservedfor the second PDCCH region 1 (Offset X1+16). The Offset X3 which is thePUCCH resource offset used in the second PDCCH region 3 having thesecond PDCCH region number #2 is obtained by adding Offset X1 to 16which is the number of ACK/NACK PUCCH resources which are reserved forthe second PDCCH region 1 and 16 which is the number of ACK/NACK PUCCHresources which are reserved for the second PDCCH region 2 (OffsetX1+16×2). In other words, the PUCCH resource offset for the second PDCCHregion of the second PDCCH region number is calculated by multiplyingthe second PDCCH region number by 16 (the number of ACK/NACK PUCCHresources which are reserved for one second PDCCH region) and by addingthe obtained value from the multiplication to Offset X1 (OffsetX1+16×second PDCCH region #). In addition, for example, when the secondPDCCH region number starts from “1”, it is possible to use the presentapplication by adjusting the calculation expression into (OffsetX1+16×(second PDCCH region #−1)).

In the case of the above configuration, a communication system of thepresent invention is a communication system which is configured with aplurality of mobile station apparatuses and a base station apparatuswhich performs communication with the plurality of mobile stationapparatuses by using a downlink control channel and an uplink controlchannel, in which a plurality of physical resource block pairs areconfigured as a downlink control channel region having a possibility ofthe downlink control channel being arranged, a first element isconfigured with a plurality of resources into which one of the physicalresource block pairs is divided, a second element is configured with anaggregation of a plurality of the first elements in the one physicalresource block pair or an aggregation of a plurality of the firstelements in the plurality of physical resource block pairs, the downlinkcontrol channel is configured with an aggregation of one or more secondelements, and a resource of the uplink control channel corresponds toeach of the second elements, in which the base station apparatusincludes a second radio resource control unit that configures aplurality of downlink control channel regions, and configures a resourceof an uplink control channel in which the association with a secondelement of the downlink control channel region is started for each ofthe downlink control channel regions, and associates informationregarding the resource of an uplink control channel in which theassociation with a second element of a downlink control channel regionwhich is configured is started with the number of a downlink controlchannel region; and a second transmission processing unit that transmitsinformation which is configured by the second radio resource controlunit, to the mobile station apparatus, and the mobile station apparatusincludes a first radio resource control unit that configures a pluralityof downlink control channel regions, based on information received fromthe base station apparatus which is configured by the second radioresource control unit; and a first control unit that configures theresource of the uplink control channel in which the association with thesecond element of the downlink control channel region is started, foreach of the downlink control channel regions that are configured by thefirst radio resource control unit, based on the downlink control channelregion number which is received from the base station apparatus.

In addition, in the embodiments of the present invention, for simplicityof explanation, the region of the resource in which the second PDCCH maybe allocated is defined as the second PDCCH region, however, even if itis defined as a different term (for example, ePDCCH set), as long as ithas an analogous meaning, it is obvious that the present invention canbe applied thereto.

Further, the mobile station apparatus 5 is not limited to a movingterminal, and the present invention may be realized by implementing thefunction of the mobile station apparatus 5 in a fixed terminal.

The characteristic units of the present invention described above can berealized by implementing functions in an integrated circuit andcontrolling the functions. In other words, an integrated circuit of thepresent invention is an integrated circuit in which a plurality ofphysical resource block pairs are configured as a downlink controlchannel region in which a downlink control channel may be arranged, afirst element is configured with a plurality of resources into which theone physical resource block pair is divided, a second element isconfigured with an aggregation of a plurality of the first elements inthe one physical resource block pair or an aggregation of a plurality ofthe first elements in a plurality of the physical resource block pairs,a downlink control channel is configured with an aggregation of one ormore second elements, and a resource of an uplink control channelcorresponds to each of second elements, and which is implemented in amobile station apparatus which performs communication with a basestation apparatus by using the downlink control channel and the uplinkcontrol channel, including a first reception processing unit thatreceives information indicating a plurality of downlink control channelregions and information indicating a resource of an uplink controlchannel in which the association with a second element of a downlinkcontrol channel region is started for each of the downlink controlchannel regions, from the base station apparatus; a first radio resourcecontrol unit that configures a plurality of downlink control channelregions, based on information which is received by the first receptionprocessing unit; and a first control unit that configures a resource ofan uplink control channel in which the association with a second elementof a downlink control channel region is started, based on informationwhich is received by the first reception processing unit for each of thedownlink control channel regions which are configured by the first radioresource control unit.

Further, in the integrated circuit of the present invention, the uplinkcontrol channel is used for transmission and reception of a receptionconfirmation acknowledgement, and the reception confirmationacknowledgement is a reception confirmation acknowledgement for data ofthe downlink shared channel of which resource allocation information isindicated by the downlink control channel.

Further, in the integrated circuit of the present invention, the firstcontrol unit determines the identification number of a resource of theuplink control channel used for transmission of a reception confirmationacknowledgement, based on the identification number of one or moresecond elements configuring the downlink control channel includinginformation of resource allocation of the downlink shared channel and aresource of the uplink control channel in which the association with asecond element of a downlink control channel region in which thedownlink control channel is detected is started.

Further, an integrated circuit of the present invention is an integratedcircuit in which a plurality of physical resource block pairs areconfigured as a downlink control channel region in which a downlinkcontrol channel may be arranged, a first element is configured with aplurality of resources into which the one physical resource block pairis divided, a second element is configured with an aggregation of aplurality of the first elements in the one physical resource block pairor an aggregation of a plurality of the first elements in a plurality ofthe physical resource block pairs, a downlink control channel isconfigured with an aggregation of one or more second elements, and aresource of an uplink control channel corresponds to each of secondelement, and which is implemented in a base station apparatus whichperforms communication with a plurality of mobile station apparatuses byusing the downlink control channel and the uplink control channel,including a second radio resource control unit that configures aplurality of downlink control channel regions, and configures a resourceof an uplink control channel in which the association with a secondelement of a downlink control channel region is started for eachdownlink control channel region; and a second transmission processingunit that transmits information which is configured by the second radioresource control unit, to the mobile station apparatus.

The operations described in the embodiments of the present invention maybe realized by a program. A program operating in the mobile stationapparatus 5 and the base station apparatus 3 according to the presentinvention is a program (a program for causing a computer to function)for controlling a CPU and so forth so as to implement the functions ofthe foregoing embodiments according to the present invention. Suchinformation as handled by apparatuses is temporarily accumulated in aRAM while being processed, and then is stored in various ROMs and HDDs.The information is read by the CPU as necessary, for modification andwriting. A recording medium having the program stored therein may be anyof semiconductor media (for example, a ROM, a non-volatile memory card,and the like), optical recording media (for example, a DVD, an MO, anMD, a CD, a BD, and the like), magnetic recording media (for example, amagnetic tape, a flexible disk, and the like), and so forth.Furthermore, in addition to the implementation of the functions of theembodiments described above by executing the loaded program, thefunctions of the present invention may be implemented by processing theprogram in cooperation with an operating system, any other applicationprogram, or the like, based on instructions of the program.

In a case where the program is Distributed on market, the program may bestored in a transportable recording medium for distribution, or may betransferred to a server computer connected through a network such as theInternet. In this case, a storage device in the server computer alsofalls within the scope of the present invention. In addition, all or apart of the mobile station apparatus 5 and the base station apparatus 3in the embodiments described above may be implemented as an LSI, whichis typically an integrated circuit. The respective functional blocks ofthe mobile station apparatus 5 and the base station apparatus 3 may beindividually built into chips, or some or all of them may be integratedand built into a chip. The method for forming an integrated circuit isnot limited to LSI, and may be implemented by a dedicated circuit or ageneral-purpose processor. In the case of the advent of integratedcircuit technology replacing LSI due to the advancement of semiconductortechnology, it is also possible to use an integrated circuit based onthis technology. The respective functional blocks of the mobile stationapparatus 5 and the base station apparatus 3 may be implemented by aplurality of circuits.

Information and signal may be represented using any various differenttechnologies and methods. For example, chips, symbols, bits, signals,information, commands, instructions, and data which may be referred tothrough the above description may be represented by voltages, currents,electromagnetic waves, magnetic fields or magnetic particles, opticalfields or light particles, or the combination thereof.

Various exemplary logical blocks, processing units and the algorithmsteps which are described in connection with the disclosure herein canbe implemented by electronic hardware, computer software, or thecombination of both. To clearly illustrate the synonymy of hardware andsoftware, various exemplary elements, blocks, modules, circuits, andsteps have been described generally with respect to theirfunctionalities. Whether such functionalities are to be implemented assoftware or to be implemented as hardware will depend on individualapplications and the design constraints imposed on the overall system.Although those skilled in the art may implement the describedfunctionality by various methods regarding respective specificapplications, determination of such implementation should not beinterpreted as departing from the scope of this disclosure.

Various exemplary logical blocks and processing units described inconnection with the disclosure herein may be implemented or performed bya general purpose application processor, a digital signal processor(DSP), an application specific integrated circuit (ASIC), a fieldprogrammable gate array signal (FPGA), or other programmable logicdevices, a discrete gate or transistor logic, discrete hardwarecomponents, or combinations thereof which are designed to perform thefunctions described herein. The general purpose application processormay be a microprocessor, and instead thereof, may be processors in therelated art, controllers, microcontrollers, or state machines. Theprocessor may also be implemented as a combination of the computingdevices. For example, the process may be a combination of the DSP andthe microprocessor, a combination of a plurality of microprocessors, acombination of a DSP core and one or more microprocessors which areconnected, or a combination of other such configurations.

The steps of a method or an algorithm described in connection with thedisclosure herein may be embodied directly by hardware, a softwaremodule which is executed by a processor, or by a combination of these.The software module may be present in a RAM memory, a flash memory, aROM memory, a EPROM memory, a EEPROM memory, a register, a hard disk, aremovable disk, a CD-ROM, or a recording medium in any form known in thefield. The typical recording medium may be coupled to a processor suchthat the processor can read information from the recording medium or canwrite information on the recording medium. In an alternative method, therecording medium may be integrated into the processor. The recordingmedium and the processor may be present in an ASIC. The ASIC may bepresent in the mobile station apparatus (user terminal). Alternatively,the processor and the recording medium may be present in the mobilestation apparatus 5 as a discrete element.

In one or more typical designs, the described functions may beimplemented by hardware, software, firmware, or a combination thereof.If the functions are implemented by software, the functions are held asone or more commands or codes on a computer-readable medium, or may betransmitted. Computer-readable media includes both communication mediaincluding any medium that facilitates carrying of computer programs fromone place to another place and computer storage media. Recording mediamay be any media that can be accessed by a general purpose or a specialpurpose computer. While not being limited thereto, suchcomputer-readable media may include a RAM, a ROM, an EEPROM, a CDROM orother optical disc media, magnetic disk media or other magneticrecording media, or available media that are accessible by a generalpurpose or a special purpose computer, or a general purpose or a specialpurpose processor in order to carry or hold desired program code meansin the form of instructions or data structures. Further, any connectionis appropriately referred to as a computer-readable medium. For example,when software is transmitted from web sites, servers, or other remotesources using wireless technologies such as a coaxial cable, a fiberoptic cable, a twisted pair, a digital subscriber line (DSL), or aninfrared, a radio, or a microwave, the coaxial cable, the fiber opticcable, the twisted pair, the DSL, or the infrared, the radio, or themicrowave are included in the definition of medium. The disk (disc) asused herein includes a compact disk (CD), a laser disc (registeredtrademark), an optical disc, a digital versatile disc (DVD), a floppy(registered trademark) disk and a blu-ray disc. While the disk (disk)generally reproduces data magnetically, the disk (disc) reproduces dataoptically with lasers. A combination of the above should also beincluded in the computer-readable medium.

(1) The present invention includes the following units in order toachieve the above objects. In other words, a communication system of thepresent invention is a communication system which is configured with aplurality of mobile station apparatuses and a base station apparatuswhich performs communication with the plurality of mobile stationapparatuses by using a downlink control channel and an uplink controlchannel, in which a plurality of physical resource block pairs areconfigured as a downlink control channel region having a possibility ofthe downlink control channels being arranged, a first element isconfigured with a plurality of resources into which one of the physicalresource block pairs is divided, a second element is configured with anaggregation of a plurality of the first elements in the one physicalresource block pair or an aggregation of a plurality of the firstelements in the plurality of physical resource block pairs, the downlinkcontrol channel is configured with an aggregation of one or more secondelements, and a resource of the uplink control channel corresponds toeach of the second elements, in which the base station apparatusincludes a second radio resource control unit that configures aplurality of downlink control channel regions, and configures a resourceof an uplink control channel in which the association with a secondelement of the downlink control channel region is started for each ofthe downlink control channel regions; and a second transmissionprocessing unit that transmits information which is configured by thesecond radio resource control unit, to the mobile station apparatus, andthe mobile station apparatus includes a first radio resource controlunit that configures a plurality of downlink control channel regions,based on information received from the base station apparatus which isconfigured by the second radio resource control unit; and a firstcontrol unit that configures the resource of the uplink control channelin which the association with the second element of the downlink controlchannel region is started, for each of the downlink control channelregions that are configured by the first radio resource control unit,based on information received from the base station apparatus which isconfigured by the second radio resource control unit.

(2) Further, in the communication system of the present invention, theuplink control channel is used in transmission and reception of areception confirmation acknowledgement, and the reception confirmationacknowledgement is a reception confirmation acknowledgement for data ofdownlink shared channel of which resource allocation information isrepresented by the downlink control channel.

(3) Further, in the communication system of the present invention, thefirst control unit determines an identification number of a resource ofthe uplink control channel used in transmission of the receptionconfirmation acknowledgement, based on identification numbers of one ormore second elements configuring the downlink control channel, whichcontains resource allocation information of the downlink shared channeland a uplink control channel resource in which the association with asecond element of a downlink control channel region from which thedownlink control channel is detected is started.

(4) Further, a mobile station apparatus of the present invention is amobile station apparatus which performs communication with a basestation apparatus by using a downlink control channel and an uplinkcontrol channel, in which a plurality of physical resource block pairsare configured as a downlink control channel region having a possibilityof the downlink control channels being arranged, a first element isconfigured with a plurality of resources into which one of the physicalresource block pairs is divided, a second element is configured with anaggregation of a plurality of the first elements in the one physicalresource block pair or an aggregation of a plurality of the firstelements in the plurality of physical resource block pairs, the downlinkcontrol channel is configured with an aggregation of one or more secondelements, and a resource of the uplink control channel corresponds toeach of the second elements, in which the mobile station apparatusincludes a first reception processing unit that receives informationindicating a plurality of downlink control channel regions andinformation indicating a resource of the uplink control channel in whichthe association with a second element of the downlink control channelregion is started for each of the downlink control channel regions, fromthe base station apparatus; a first radio resource control unit thatconfigures a plurality of downlink control channel regions, based oninformation which is received by the first reception processing unit;and a first control unit that configures a resource of the uplinkcontrol channel in which the association with a second element of adownlink control channel region is started, based on information whichis received by the first reception processing unit, for each of thedownlink control channel regions which are configured by the first radioresource control unit.

(5) Further, in the mobile station apparatus of the present invention,the uplink control channel is used in transmission and reception of areception confirmation acknowledgement, and the reception confirmationacknowledgement is a reception confirmation acknowledgement for data ofdownlink shared channel of which resource allocation information isrepresented by the downlink control channel.

(6) Further, in the mobile station apparatus of the present invention,the first control unit determines identification number of a resource ofthe uplink control channel used in transmission of the receptionconfirmation acknowledgement, based on identification numbers of one ormore second elements configuring the downlink control channel, whichcontains resource allocation information of the downlink shared channeland a uplink control channel resource in which the association with asecond element of a downlink control channel region from which thedownlink control channel is detected is started.

(7) Further, a base station apparatus of the present invention is a basestation apparatus which performs communication with a plurality ofmobile station apparatuses by using a downlink control channel and anuplink control channel, in which a plurality of physical resource blockpairs are configured as a downlink control channel region having apossibility of the downlink control channels being arranged, a firstelement is configured with a plurality of resources into which one ofthe physical resource block pairs is divided, a second element isconfigured with an aggregation of a plurality of the first elements inthe one physical resource block pair or an aggregation of a plurality ofthe first elements in the plurality of physical resource block pairs,the downlink control channel is configured with an aggregation of one ormore second elements, and a resource of the uplink control channelcorresponds to each of the second elements, in which the base stationapparatus includes a second radio resource control unit that configuresa plurality of downlink control channel regions, and configures aresource of an uplink control channel in which the association with asecond element of the downlink control channel region is started foreach of the downlink control channel regions; and a second transmissionprocessing unit that transmits information which is configured by thesecond radio resource control unit, to the mobile station apparatus.

(8) Further, a communication method of the present invention is acommunication method which is used in a mobile station apparatus thatperforms communication with a base station apparatus by using a downlinkcontrol channel and an uplink control channel, in which a plurality ofphysical resource block pairs are configured as a downlink controlchannel region having a possibility of the downlink control channelsbeing arranged, a first element is configured with a plurality ofresources into which one of the physical resource block pairs isdivided, a second element is configured with an aggregation of aplurality of the first elements in the one physical resource block pairor an aggregation of a plurality of the first elements in the pluralityof physical resource block pairs, the downlink control channel isconfigured with an aggregation of one or more second elements, and aresource of the uplink control channel corresponds to each of the secondelements, in which the communication method includes at least a step ofreceiving information indicating a plurality of downlink control channelregions and information indicating a resource of the uplink controlchannel in which the association with a second element of the downlinkcontrol channel region is started for each of the downlink controlchannel regions, from the base station apparatus; a step of configuringa plurality of downlink control channel regions, based on informationwhich is received; and a step of configuring a resource of the uplinkcontrol channel in which the association with a second element of adownlink control channel region is started, based on information whichis received, for each of the downlink control channel regions which areconfigured.

(9) Further, in the communication method of the present invention, theuplink control channel is used in transmission and reception of areception confirmation acknowledgement, and the reception confirmationacknowledgement is a reception confirmation acknowledgement for data ofdownlink shared channel of which resource allocation information isrepresented by the downlink control channel.

(10) Further, the communication method of the present invention furtherincludes a step of determining identification number of a resource ofthe uplink control channel used in transmission of the receptionconfirmation acknowledgement, based on identification numbers of one ormore second elements configuring the downlink control channel, whichcontains resource allocation information of the downlink shared channel,and a uplink control channel resource in which the association with asecond element of a downlink control channel region from which thedownlink control channel is detected is started.

(11) Further, a communication method of the present invention is acommunication method which is used in a base station apparatus whichperforms communication with a plurality of mobile station apparatuses byusing a downlink control channel and an uplink control channel, in whicha plurality of physical resource block pairs are configured as adownlink control channel region having a possibility of the downlinkcontrol channels being arranged, a first element is configured with aplurality of resources into which one of the physical resource blockpairs is divided, a second element is configured with an aggregation ofa plurality of the first elements in the one physical resource blockpair or an aggregation of a plurality of the first elements in theplurality of physical resource block pairs, the downlink control channelis configured with an aggregation of one or more second elements, and aresource of the uplink control channel corresponds to each of the secondelements, in which the communication method includes a step ofconfiguring a plurality of downlink control channel regions, andconfiguring a resource of an uplink control channel in which theassociation with a second element of the downlink control channel regionis started for each of the downlink control channel regions; and a stepof transmitting information which is configured to the mobile stationapparatus.

(12) Further, an integrated circuit of the present invention is anintegrated circuit which is implemented in a mobile station apparatusthat performs communication with a base station apparatus by using adownlink control channel and an uplink control channel, in which aplurality of physical resource block pairs are configured as a downlinkcontrol channel region having a possibility of the downlink controlchannels being arranged, a first element is configured with a pluralityof resources into which one of the physical resource block pairs isdivided, a second element is configured with an aggregation of aplurality of the first elements in the one physical resource block pairor an aggregation of a plurality of the first elements in the pluralityof physical resource block pairs, the downlink control channel isconfigured with an aggregation of one or more second elements, and aresource of the uplink control channel corresponds to each of the secondelements, in which the integrated circuit includes a first receptionprocessing unit that receives information indicating a plurality ofdownlink control channel regions and information indicating a resourceof the uplink control channel in which the association with a secondelement of the downlink control channel region is started for each ofthe downlink control channel regions, from the base station apparatus; afirst radio resource control unit that configures a plurality ofdownlink control channel regions, based on information which is receivedby the first reception processing unit; and a first control unit thatconfigures a resource of the uplink control channel in which theassociation with a second element of a downlink control channel regionis started, based on information which is received by the firstreception processing unit, for each of the downlink control channelregions which are configured by the first radio resource control unit.

(13) Further, in the integrated circuit of the present invention, theuplink control channel is used in transmission and reception of areception confirmation acknowledgement, and the reception confirmationacknowledgement is a reception confirmation acknowledgement for data ofdownlink shared channel of which resource allocation information isrepresented by the downlink control channel.

(14) Further, in the integrated circuit of the present invention, thefirst control unit determines identification number of a resource of theuplink control channel used in transmission of the receptionconfirmation acknowledgement, based on identification numbers of one ormore second elements configuring the downlink control channel, whichcontains resource allocation information of the downlink shared channeland a uplink control channel resource in which the association with asecond element of a downlink control channel region from which thedownlink control channel is detected is started.

(15) Further, an integrated circuit of the present invention is anintegrated circuit which is implemented in a base station apparatuswhich performs communication with a plurality of mobile stationapparatuses by using a downlink control channel and an uplink controlchannel, in which a plurality of physical resource block pairs areconfigured as a downlink control channel region having a possibility ofthe downlink control channels being arranged, a first element isconfigured with a plurality of resources into which one of the physicalresource block pairs is divided, a second element is configured with anaggregation of a plurality of the first elements in the one physicalresource block pair or an aggregation of a plurality of the firstelements in the plurality of physical resource block pairs, the downlinkcontrol channel is configured with an aggregation of one or more secondelements, and a resource of the uplink control channel corresponds toeach of the second elements, in which the integrated circuit includes asecond radio resource control unit that configures a plurality ofdownlink control channel regions, and configures a resource of an uplinkcontrol channel in which the association with a second element of thedownlink control channel region is started for each of the downlinkcontrol channel regions; and a second transmission processing unit thattransmits information which is configured by the second radio resourcecontrol unit, to the mobile station apparatus.

While embodiments of this invention have been described in detail withreference to the drawings, a specific configuration is not limited tothese embodiments, and the claims also includes design changes and thelike without departing from the essence of this invention.

DESCRIPTION OF REFERENCE NUMERALS

-   -   3 BASE STATION APPARATUS,    -   4 (A TO C) RRH,    -   5 (A TO C) MOBILE STATION APPARATUS,    -   101 RECEPTION PROCESSING UNIT,    -   103 RADIO RESOURCE CONTROL UNIT,    -   105 CONTROL UNIT,    -   107 TRANSMISSION PROCESSING UNIT,    -   109 RECEIVE ANTENNA,    -   111 TRANSMIT ANTENNA,    -   201 PHYSICAL DOWNLINK SHARED CHANNEL PROCESSING UNIT,    -   203 PHYSICAL DOWNLINK CONTROL CHANNEL PROCESSING UNIT,    -   205 DOWNLINK PILOT CHANNEL PROCESSING UNIT,    -   207 MULTIPLEXING UNIT,    -   209 IFFT UNIT,    -   211 GI INSERTION UNIT,    -   213 D/A UNIT,    -   215 TRANSMISSION RF UNIT,    -   219 TURBO CODING UNIT,    -   221 DATA MODULATION UNIT,    -   223 CONVOLUTIONAL CODING UNIT,    -   225 QPSK MODULATION UNIT,    -   227 PRE-CODING PROCESSING UNIT (FOR PDCCH),    -   229 PRE-CODING PROCESSING UNIT (FOR PDSCH),    -   231 PRE-CODING PROCESSING UNIT (FOR DOWNLINK PILOT CHANNEL),    -   301 RECEPTION RF UNIT,    -   303 A/D UNIT,    -   309 SYMBOL TIMING DETECTION UNIT,    -   311 GI REMOVING UNIT,    -   313 FFT UNIT,    -   315 SUBCARRIER DEMAPPING UNIT,    -   317 CHANNEL ESTIMATION UNIT,    -   319 CHANNEL EQUALIZATION UNIT (FOR PUSCH),    -   321 CHANNEL EQUALIZATION UNIT (FOR PUCCH),    -   323 IDFT UNIT,    -   325 DATA DEMODULATION UNIT,    -   327 TURBO DECODING UNIT,    -   329 PHYSICAL UPLINK CONTROL CHANNEL DETECTION UNIT,    -   331 PREAMBLE DETECTION UNIT,    -   333 SRS PROCESSING UNIT,    -   401 RECEPTION PROCESSING UNIT,    -   403 RADIO RESOURCE CONTROL UNIT,    -   405 CONTROL UNIT,    -   407 TRANSMISSION PROCESSING UNIT,    -   409 RECEIVE ANTENNA,    -   411 TRANSMIT ANTENNA,    -   501 RECEPTION RF UNIT,    -   503 A/D UNIT,    -   505 SYMBOL TIMING DETECTION UNIT,    -   507 GI REMOVING UNIT,    -   509 FFT UNIT,    -   511 DEMULTIPLEXING UNIT,    -   513 CHANNEL ESTIMATION UNIT,    -   515 CHANNEL COMPENSATION UNIT (FOR PDSCH),    -   517 PHYSICAL DOWNLINK SHARED CHANNEL DECODING UNIT,    -   519 CHANNEL COMPENSATION UNIT (FOR PDCCH),    -   521 PHYSICAL DOWNLINK CONTROL CHANNEL DECODING UNIT,    -   523 DATA DEMODULATION UNIT,    -   525 TURBO DECODING UNIT,    -   527 QPSK DEMODULATION UNIT,    -   529 VITERBI DECODER UNIT,    -   531 DOWNLINK RECEPTION QUALITY MEASUREMENT UNIT,    -   533 PDCCH DEMAPPING UNIT,    -   605 D/A UNIT,    -   607 TRANSMISSION RF UNIT,    -   611 TURBO CODING UNIT,    -   613 DATA MODULATION UNIT,    -   615 DFT UNIT,    -   617 UPLINK PILOT CHANNEL PROCESSING UNIT,    -   619 PHYSICAL UPLINK CONTROL CHANNEL PROCESSING UNIT,    -   621 SUBCARRIER MAPPING UNIT,    -   623 IFFT UNIT,    -   625 GI INSERTION UNIT,    -   627 TRANSMISSION POWER ADJUSTMENT UNIT,    -   629 RANDOM ACCESS CHANNEL PROCESSING UNIT

The invention claimed is:
 1. A terminal apparatus configured tocommunicate with a base station apparatus, the terminal apparatuscomprising: a radio resource controller configured to and/or programmedto configure, based on a radio resource control (RRC) signaling, a firstenhanced physical downlink control channel (EPDCCH) set and a secondEPDCCH set for EPDCCH monitoring, and configure a transmission type ofthe first EPDCCH set and a transmission type of the second EPDCCH setwith a localized transmission type or a distributed transmission type;the transmission type of the first EPDCCH set and the transmission typeof the second EPDCCH set being configured with a same transmission type,a receiver configured to and/or programmed to monitor a set of EPDCCHcandidates based on the first EPDCCH set and the second EPDCCH set, afirst physical uplink control channel (PUCCH) resource offset beingconfigured for the first EPDCCH set by the RRC signaling, a second PUCCHresource offset being configured for the second EPDCCH set by the RRCsignaling; and a transmitter configured to and/or programmed to transmita hybrid automatic repeat request-acknowledgement (HARQ-ACK) for aphysical downlink shared channel transmission indicated by a detectionof an EPDCCH, the HARQ-ACK being transmitted using a PUCCH resource,wherein each of the first EPDCCH set and the second EPDCCH set consistsof a plurality of physical resource block pairs, in a case that theEPDCCH is in the first EPDCCH set, the PUCCH resource is determinedbased on at least a lowest enhanced control channel element (ECCE) indexused to construct the EPDCCH and the first PUCCH resource offset, in acase that the EPDCCH is in the second EPDCCH set, the PUCCH resource isdetermined based on at least a lowest enhanced control channel element(ECCE) index used to construct the EPDCCH and the second PUCCH resourceoffset.
 2. A base station apparatus configured to communicate with aterminal apparatus, the base station apparatus comprising: a radioresource controller configured to and/or programmed to configure, basedon a radio resource control (RRC) signaling, a first enhanced physicaldownlink control channel (EPDCCH) set and a second EPDCCH set for EPDCCHmonitoring, configure a reception type of the first EPDCCH set and areception type of the second EPDCCH set with a localized reception typeor a distributed reception type, the reception type of the first EPDCCHset and the reception type of the second EPDCCH set being configuredwith a same reception type; a transmitter configured to and/orprogrammed to transmit an EPDCCH based on the first EPDCCH set and thesecond EPDCCH set, a first physical uplink control channel (PUCCH)resource offset being configured by the RRC signaling for the firstEPDCCH set, and a second PUCCH resource offset being configured by theRRC signaling for the second EPDCCH set; and a receiver configured toand/or programmed to receive a hybrid automatic repeatrequest-acknowledgement (HARQ-ACK) for a physical downlink sharedchannel transmission indicated by a detection of the EPDCCH, theHARQ-ACK being received using a PUCCH resource, wherein each of thefirst EPDCCH set and the second EPDCCH set consists of a plurality ofphysical resource block pairs, in a case that the EPDCCH is in the firstEPDCCH set, the PUCCH resource is determined based on at least a lowestenhanced control channel element (ECCE) index used to construct theEPDCCH and the first PUCCH resource offset, in a case that the EPDCCH isin the second EPDCCH set, the PUCCH resource is determined based on atleast a lowest enhanced control channel element (ECCE) index used toconstruct the EPDCCH and the second PUCCH resource offset.
 3. Acommunication method for a terminal apparatus configured to communicatewith a base station apparatus, the communication method comprising:configuring, based on a radio resource control (RRC) signaling, a firstenhanced physical downlink control channel (EPDCCH) set and a secondEPDCCH set for EPDCCH monitoring, configuring a transmission type of thefirst EPDCCH set and a transmission type of the second EPDCCH set with alocalized transmission type or a distributed transmission type, thetransmission type of the first EPDCCH set and the transmission type ofthe second EPDCCH set being configured with a same transmission type;monitoring a set of EPDCCH candidates based on the first EPDCCH set andthe second EPDCCH set, a first physical uplink control channel (PUCCH)resource offset being configured by the RRC signaling, a second PUCCHresource offset being configured by the RRC signaling; and transmittinga hybrid automatic repeat request-acknowledgement (HARQ-ACK) for aphysical downlink shared channel transmission indicated by a detectionof an EPDCCH, the HARQ-ACK being transmitted using a PUCCH resource,wherein each of the first EPDCCH set and the second EPDCCH set consistsof a plurality of physical resource block pairs, in a case that theEPDCCH is in the first EPDCCH set, the PUCCH resource is determinedbased on at least a lowest enhanced control channel element (ECCE) indexused to construct the EPDCCH and the first PUCCH resource offset, in acase that the EPDCCH is in the second EPDCCH set, the PUCCH resource isdetermined based on at least a lowest enhanced control channel element(ECCE) index used to construct the EPDCCH and the second PUCCH resourceoffset.
 4. A communication method for a base station apparatusconfigured to communicate with a terminal apparatus, the communicationmethod comprising: configuring, based on a radio resource control (RRC)signaling, a first enhanced physical downlink control channel (EPDCCH)set and a second EPDCCH set for EPDCCH monitoring, configuring areception type of the first EPDCCH set and a reception type of thesecond EPDCCH set with a localized reception type or a distributedreception type, the reception type of the first EPDCCH set and thereception type of the second EPDCCH set being configured with a samereception type; transmitting an EPDCCH based on the first EPDCCH set andthe second EPDCCH set, a first physical uplink control channel (PUCCH)resource offset being configured by the RRC signaling and a second PUCCHresource offset being configured by the RRC signaling; and receiving ahybrid automatic repeat request-acknowledgement (HARQ-ACK) for aphysical downlink shared channel transmission indicated by a detectionof the EPDCCH, the HARQ-ACK being received using a PUCCH resource,wherein each of the first EPDCCH set and the second EPDCCH set consistsof a plurality of physical resource block pairs, in a case that theEPDCCH is in the first EPDCCH set, the PUCCH resource is determinedbased on at least a lowest enhanced control channel element (ECCE) indexused to construct the EPDCCH and the first PUCCH resource offset, in acase that the EPDCCH is in the second EPDCCH set, the PUCCH resource isdetermined based on at least a lowest enhanced control channel element(ECCE) index used to construct the EPDCCH and the second PUCCH resourceoffset.